Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Optimizing modulation frequency for structured illumination in a fiber-optic microendoscope to image nuclear morphometry in columnar epithelium.

Literature DB >> 25798311

Optimizing modulation frequency for structured illumination in a fiber-optic microendoscope to image nuclear morphometry in columnar epithelium.

P A Keahey¹, T S Tkaczyk¹, K M Schmeler², R R Richards-Kortum¹.

Abstract

Fiber-optic microendoscopes have shown promise to image the changes in nuclear morphometry that accompany the development of precancerous lesions in tissue with squamous epithelium such as in the oral mucosa and cervix. However, fiber-optic microendoscopy image contrast is limited by out-of-focus light generated by scattering within tissue. The scattering coefficient of tissues with columnar epithelium can be greater than that of squamous epithelium resulting in decreased image quality. To address this challenge, we present a small and portable microendoscope system capable of performing optical sectioning using structured illumination (SI) in real-time. Several optical phantoms were developed and used to quantify the sectioning capabilities of the system. Columnar epithelium from cervical tissue specimens was then imaged ex vivo, and we demonstrate that the addition of SI achieves higher image contrast, enabling visualization of nuclear morphology.

Entities: Disease

Keywords: (060.2350) Fiber optics imaging; (170.0170) Medical optics and biotechnology; (170.1610) Clinical applications; (170.2150) Endoscopic imaging; (170.2520) Fluorescence microscopy; (170.6935) Tissue characterization

Year: 2015 PMID： 25798311 PMCID： PMC4361441 DOI： 10.1364/BOE.6.000870

Source DB: PubMed Journal: Biomed Opt Express ISSN： 2156-7085 Impact factor: 3.732

19 in total

1. Trimodal spectroscopy for the detection and characterization of cervical precancers in vivo.

Authors: Irene Georgakoudi; Ellen E Sheets; Markus G Müller; Vadim Backman; Christopher P Crum; Kamran Badizadegan; Ramachandra R Dasari; Michael S Feld
Journal: Am J Obstet Gynecol Date: 2002-03 Impact factor: 8.661

2. Fast optical sectioning obtained by structured illumination microscopy using a digital mirror device.

Authors: Dongli Xu; Tao Jiang; Anan Li; Bihe Hu; Zhao Feng; Hui Gong; Shaoqun Zeng; Qingming Luo
Journal: J Biomed Opt Date: 2013-06 Impact factor: 3.170

3. Axial response of high-resolution microendoscopy in scattering media.

Authors: Michael H Koucky; Mark C Pierce
Journal: Biomed Opt Express Date: 2013-09-25 Impact factor: 3.732

4. Quantitative analysis of high-resolution microendoscopic images for diagnosis of esophageal squamous cell carcinoma.

Authors: Dongsuk Shin; Marion-Anna Protano; Alexandros D Polydorides; Sanford M Dawsey; Mark C Pierce; Michelle Kang Kim; Richard A Schwarz; Timothy Quang; Neil Parikh; Manoop S Bhutani; Fan Zhang; Guiqi Wang; Liyan Xue; Xueshan Wang; Hong Xu; Sharmila Anandasabapathy; Rebecca R Richards-Kortum
Journal: Clin Gastroenterol Hepatol Date: 2014-07-25 Impact factor: 11.382

5. A fiber-optic fluorescence microscope using a consumer-grade digital camera for in vivo cellular imaging.

Authors: Dongsuk Shin; Mark C Pierce; Ann M Gillenwater; Michelle D Williams; Rebecca R Richards-Kortum
Journal: PLoS One Date: 2010-06-23 Impact factor: 3.240

6. Accuracy and interrater reliability for the diagnosis of Barrett's neoplasia among users of a novel, portable high-resolution microendoscope.

Authors: P M Vila; M J Kingsley; A D Polydorides; M-A Protano; M C Pierce; J Sauk; M K Kim; K Patel; J H Godbold; J D Waye; R Richards-Kortum; S Anandasabapathy
Journal: Dis Esophagus Date: 2013-02-26 Impact factor: 3.429

7. High-resolution imaging in Barrett's esophagus: a novel, low-cost endoscopic microscope.

Authors: Timothy J Muldoon; Sharmila Anandasabapathy; Dipen Maru; Rebecca Richards-Kortum
Journal: Gastrointest Endosc Date: 2008-10 Impact factor: 9.427

8. Subcellular-resolution molecular imaging within living tissue by fiber microendoscopy.

Authors: Timothy J Muldoon; Mark C Pierce; Dawn L Nida; Michelle D Williams; Ann Gillenwater; Rebecca Richards-Kortum
Journal: Opt Express Date: 2007-12-10 Impact factor: 3.894

9. High-resolution microendoscopy for the detection of cervical neoplasia in low-resource settings.

Authors: Mary K Quinn; Tefo C Bubi; Mark C Pierce; Mukendi K Kayembe; Doreen Ramogola-Masire; Rebecca Richards-Kortum
Journal: PLoS One Date: 2012-09-18 Impact factor: 3.240

10. Noninvasive imaging of oral neoplasia with a high-resolution fiber-optic microendoscope.

Authors: Timothy J Muldoon; Darren Roblyer; Michelle D Williams; Vanda M T Stepanek; Rebecca Richards-Kortum; Ann M Gillenwater
Journal: Head Neck Date: 2011-03-16 Impact factor: 3.147

8 in total

1. Line-scanning fiber bundle endomicroscopy with a virtual detector slit.

Authors: Michael Hughes; Guang-Zhong Yang
Journal: Biomed Opt Express Date: 2016-05-18 Impact factor: 3.732

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

Authors: Pelham Keahey; Preetha Ramalingam; Kathleen Schmeler; Rebecca R Richards-Kortum
Journal: Proc Natl Acad Sci U S A Date: 2016-09-12 Impact factor: 11.205

3. Feasibility of clinical detection of cervical dysplasia using angle-resolved low coherence interferometry measurements of depth-resolved nuclear morphology.

Authors: Derek Ho; Tyler K Drake; Karen K Smith-McCune; Teresa M Darragh; Loris Y Hwang; Adam Wax
Journal: Int J Cancer Date: 2017-03-15 Impact factor: 7.396

4. Fiber-bundle microendoscopy with sub-diffuse reflectance spectroscopy and intensity mapping for multimodal optical biopsy of stratified epithelium.

Authors: Gage J Greening; Haley M James; Amy J Powless; Joshua A Hutcheson; Mary K Dierks; Narasimhan Rajaram; Timothy J Muldoon
Journal: Biomed Opt Express Date: 2015-11-19 Impact factor: 3.732