In Vivo Diagnostic Accuracy of High-Resolution Microendoscopy in Differentiating Neoplastic from Non-Neoplastic Colorectal Polyps: A Prospective Study

Parikh, Neil; Perl, Daniel P.; Lee, Michelle H.; Shah, Brijen J.; Young, Yuki; Chang, Shannon; Shukla, Richa; Polydorides, Alexandros; Moshier, Erin; Godbold, James; Zhou, Elinor; Mitcham, Josephine; Richards‐Kortum, Rebecca; Anandasabapathy, Sharmila

doi:10.1038/ajg.2013.387

Cited by 33 publications

(34 citation statements)

References 41 publications

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“…Recent studies examining manual inspection of microendoscopy images of known diagnoses have demonstrated strong interobserver agreement, indicating that well-trained clinicians should be able to effectively incorporate these methods into clinical practice. 20 Qualitative assessment of these images by a highly trained observer is likely to continue to yield clinically relevant data, but widespread adoption of high-resolution, in vivo, microendoscopy methods for improved detection of occult dysplasia remains a challenge. A user-independent method of image analysis could provide additional data to make an informed decision and reduce the burden of training required for the clinician at the point-of-care.…”

Section: Discussionmentioning

confidence: 99%

“…17 These systems offer real-time, histology-level information to be displayed to the clinician at the time of endoscopy, potentially greatly improving biopsy targeting to locations most likely to show evidence of dysplasia. 18,19 Nonscanning, wide-field fiber bundle microendoscopy methods have also been demonstrated to yield high-resolution image data from the superficial epithelium with promising diagnostic accuracy despite the limited field of view, 20 restricted by the biopsy port (∼2 mm) through which these devices are deployed in vivo. While certain technical challenges that remain before microendoscopy methods may be widely disseminated in clinical applications, the combination of improved wide-field endoscopic methods and high-resolution microendoscopy methods may greatly improve upon currently achieved accuracy.…”

mentioning

confidence: 99%

“…While certain technical challenges that remain before microendoscopy methods may be widely disseminated in clinical applications, the combination of improved wide-field endoscopic methods and high-resolution microendoscopy methods may greatly improve upon currently achieved accuracy. 20,21 Furthermore, although several clinical trials of a high-resolution fiber bundle microendoscopy device have demonstrated excellent interobserver agreement in interpretation and classification of fiber bundle microendoscopy images of colorectal polyps, 20 there is currently no widely accepted, quantitative image analysis criteria that can be used to objectively classify fluorescence image data of colorectal polyps without human intervention. Previously demonstrated interobserver agreement of microendoscopic image interpretation is dependent on highly trained staff and physicians.…”

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confidence: 99%

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Quantitative analysis ofex vivocolorectal epithelium using an automated feature extraction algorithm for microendoscopy image data

et al. 2016

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Quantitative analysis of ex vivo colorectal epithelium using an automated feature extraction algorithm for microendoscopy image data," J. Med. Imag. 3(2), 024502 (2016), doi: 10.1117/1.JMI.3.2.024502. Abstract. Qualitative screening for colorectal polyps via fiber bundle microendoscopy imaging has shown promising results, with studies reporting high rates of sensitivity and specificity, as well as low interobserver variability with trained clinicians. A quantitative image quality control and image feature extraction algorithm (QFEA) was designed to lessen the burden of training and provide objective data for improved clinical efficacy of this method. After a quantitative image quality control step, QFEA extracts field-of-view area, crypt area, crypt circularity, and crypt number per image. To develop and validate this QFEA, a training set of microendoscopy images was collected from freshly resected porcine colon epithelium. The algorithm was then further validated on ex vivo image data collected from eight human subjects, selected from clinically normal appearing regions distant from grossly visible tumor in surgically resected colorectal tissue. QFEA has proven flexible in application to both mosaics and individual images, and its automated crypt detection sensitivity ranges from 71 to 94% despite intensity and contrast variation within the field of view. It also demonstrates the ability to detect and quantify differences in grossly normal regions among different subjects, suggesting the potential efficacy of this approach in detecting occult regions of dysplasia.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Quantitative analysis ofex vivocolorectal epithelium using an automated feature extraction algorithm for microendoscopy image data

et al. 2016

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“…[1][2][3] One such imaging technique, high-resolution fluorescence microendoscopy, can image apical tissue micro-architecture with sub-cellular resolution in a small, microscale field-of-view, using a topical contrast agent such as proflavine, fluorescein, or pyranine ink. 1,[3][4][5][6][7][8][9][10][11] This imaging modality has shown promising clinical performance in qualitatively differentiating diseased and healthy epithelial tissue in realtime with low inter-observer variability. 8 Occasionally, investigators will use high-resolution fluorescence microscopy data to extract quantitative features such as cell and nuclear size or gland area, but this remains a primarily qualitative technique targeted towards visualizing tissue morphology.…”

Section: Introductionmentioning

confidence: 99%

Multimodal Imaging and Spectroscopy Fiber-bundle Microendoscopy Platform for Non-invasive, <em>In Vivo</em> Tissue Analysis

Greening

Rajaram

Muldoon

2016

JoVE

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Recent fiber-bundle microendoscopy techniques enable non-invasive analysis of in vivo tissue using either imaging techniques or a combination of spectroscopy techniques. Combining imaging and spectroscopy techniques into a single optical probe may provide a more complete analysis of tissue health. In this article, two dissimilar modalities are combined, high-resolution fluorescence microendoscopy imaging and diffuse reflectance spectroscopy, into a single optical probe. High-resolution fluorescence microendoscopy imaging is a technique used to visualize apical tissue micro-architecture and, although mostly a qualitative technique, has demonstrated effective real-time differentiation between neoplastic and non-neoplastic tissue. Diffuse reflectance spectroscopy is a technique which can extract tissue physiological parameters including local hemoglobin concentration, melanin concentration, and oxygen saturation. This article describes the specifications required to construct the fiber-optic probe, how to build the instrumentation, and then demonstrates the technique on in vivo human skin. This work revealed that tissue micro-architecture, specifically apical skin keratinocytes, can be co-registered with its associated physiological parameters. The instrumentation and fiber-bundle probe presented here can be optimized as either a handheld or endoscopically-compatible device for use in a variety of organ systems. Additional clinical research is needed to test the viability of this technique for different epithelial disease states. Video LinkThe video component of this article can be found at

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“…When used in conjunction with contrast agents, high resolution microendoscopy (HRME) has shown promise to improve early detection of precancerous lesions based on changes in nuclear size, shape, and density (9)(10)(11)(12)(13)(14)(15). However, the coherent fiber optic bundles used in microendoscopes lack inherent optical sectioning capabilities (8); out-of-focus light generated in highly scattering tissues can result in poor image contrast that obscures cellular detail (16,17), which is particularly problematic in tissues with glandular epithelium, such as the breast, where microendoscopic images do not show sufficient contrast to differentiate between normal and neoplastic tissue (18).…”

mentioning

confidence: 99%

Differential structured illumination microendoscopy for in vivo imaging of molecular contrast agents

Keahey

Ramalingam

Schmeler

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Fiber optic microendoscopy has shown promise for visualization of molecular contrast agents used to study disease in vivo. However, fiber optic microendoscopes have limited optical sectioning capability, and image contrast is limited by out-of-focus light generated in highly scattering tissue. Optical sectioning techniques have been used in microendoscopes to remove out-of-focus light but reduce imaging speed or rely on bulky optical elements that prevent in vivo imaging. Here, we present differential structured illumination microendoscopy (DSIMe), a fiber optic system that can perform structured illumination in real time for optical sectioning without any opto-mechanical components attached to the distal tip of the fiber bundle. We demonstrate the use of DSIMe during in vivo fluorescence imaging in patients undergoing surgery for cervical adenocarcinoma in situ. Images acquired using DSIMe show greater contrast than standard microendoscopy, improving the ability to detect cellular atypia associated with neoplasia.

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In Vivo Diagnostic Accuracy of High-Resolution Microendoscopy in Differentiating Neoplastic from Non-Neoplastic Colorectal Polyps: A Prospective Study

Cited by 33 publications

References 41 publications

Quantitative analysis ofex vivocolorectal epithelium using an automated feature extraction algorithm for microendoscopy image data

Quantitative analysis ofex vivocolorectal epithelium using an automated feature extraction algorithm for microendoscopy image data

Multimodal Imaging and Spectroscopy Fiber-bundle Microendoscopy Platform for Non-invasive, <em>In Vivo</em> Tissue Analysis

Differential structured illumination microendoscopy for in vivo imaging of molecular contrast agents

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