Ex vivo confocal microscopy imaging to identify tumor tissue on freshly removed brain sample

Section: Discussionmentioning

confidence: 83%

Ex Vivo Confocal Fluorescence Microscopy for Rapid Evaluation of Tissues in Surgical Pathology Practice

Krishnamurthy¹,

Cortés²,

Lopez³

et al. 2017

“…Ex vivo microscopy gives pathologists the ability to examine fresh or fixed tissue with microscopic resolution, eliminating the need to embed the tissue in paraffin or produce a glass slide. Ex vivo microscopy has the potential to streamline laboratory workflow, 1 preserve valuable tissue for molecular assays, 2,3 and provide novel morphologic insights. 4 Each ex vivo microscopy technique has its own strengths and weakness, reflecting trade-offs among resolution, speed, cost, and ease of use.…”

mentioning

confidence: 99%

Open-Top Light-Sheet Microscopy Image Atlas of Prostate Core Needle Biopsies

Reder

Glaser

McCarty

et al. 2019

Context.— Ex vivo microscopy encompasses a range of techniques to examine fresh or fixed tissue with microscopic resolution, eliminating the need to embed the tissue in paraffin or produce a glass slide. One such technique is light-sheet microscopy, which enables rapid 3D imaging. Our pathology-engineering collaboration has resulted in an open-top light-sheet (OTLS) microscope that is specifically tailored to the needs of pathology practice. Objective.— To present an image atlas of OTLS images of prostate core needle biopsies. Design.— Core needle biopsies (N = 9) were obtained from fresh radical prostatectomy specimens. Each biopsy was fixed in formalin, dehydrated in ethanol, stained with TO-PRO3 and eosin, optically cleared, and imaged using OTLS microscopy. The biopsies were then processed, paraffin embedded, and sectioned. Hematoxylin-eosin and immunohistochemical staining for cytokeratin 5 and cytokeratin 8 was performed. Results.— Benign and neoplastic histologic structures showed high fidelity between OTLS and traditional light microscopy. OTLS microscopy had no discernible effect on hematoxylin-eosin or immunohistochemical staining in this pilot study. The 3D histology information obtained using OTLS microscopy enabled new structural insights, including the observation of cribriform and well-formed gland morphologies within the same contiguous glandular structures, as well as the continuity of poorly formed glands with well-formed glands. Conclusions.— Three-dimensional OTLS microscopy images have a similar appearance to traditional hematoxylin-eosin histology images, with the added benefit of useful 3D structural information. Further studies are needed to continue to document the OTLS appearance of a wide range of tissues and to better understand 3D histologic structures.

“…A comprehensive list of potential EVM applications was developed from a review of the published literature performed as part of the annual update of the CAP IVM Resource Guide, as well as from expert opinion within the group. 7,[9][10][11][12][13] Three EVM applications were then selected for development of detailed FRs based on currently published studies and likely wide use in pathology practice. The FR categories were formulated to encompass the requirements for pathology practice and compliance with applicable guidelines and regulations.…”

Section: Designmentioning

confidence: 99%

Development of Functional Requirements for Ex Vivo Pathology Applications of In Vivo Microscopy Systems: A Proposal From the In Vivo Microscopy Committee of the College of American Pathologists

Mathur

Fitzmaurice

Reder

et al. 2019

Context.— In vivo microscopy (IVM) allows direct, real-time visualization of tissue histology in living patients without the need for tissue removal, processing, or staining. The IVM technologies in clinical use include confocal microscopy and optical coherence tomography. These technologies also show promise for use with pathology specimens (ex vivo microscopy [EVM]). However, few systems designed for EVM are commercially available, at least in part because of the lack of defined minimal functional requirements (FRs). Objective.— To develop minimal FRs for likely high-volume pathology applications of EVM. Design.— The IVM Committee of the College of American Pathologists identified potential EVM pathology applications based on the published literature. A subcommittee of IVM and EVM early adopters and experts then defined FRs for the most likely EVM applications. Results.— Potential EVM applications include assessment of margins, adequacy of needle biopsies and aspirates for diagnosis, and transplant tissues; selection of tissue for molecular studies or biorepository; and guidance in block selection from gross specimens. The first 3 applications were selected for development of FRs. The FRs were identified based on existing laboratory practices and guidelines and input from experts in the field and included device footprint and portability, specimen preparation, imaging time, field of view or resolution, morphologic diagnostic capability, yield, accuracy, ease of use, safety, and cost. Conclusions.— Consensus was achieved on FRs that would accommodate the selected EVM applications. Publication and dissemination of those FRs will provide guidance to engineers, researchers, and vendors on how to optimally adapt IVM technologies for EVM for widespread adoption by pathologists.