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 Imaging deep skeletal muscle structure using a high-sensitivity ultrathin side-viewing optical coherence tomography needle probe.

Literature DB >> 24466482

Imaging deep skeletal muscle structure using a high-sensitivity ultrathin side-viewing optical coherence tomography needle probe.

Xiaojie Yang¹, Dirk Lorenser¹, Robert A McLaughlin¹, Rodney W Kirk¹, Matthew Edmond², M Cather Simpson², Miranda D Grounds³, David D Sampson⁴.

Abstract

We have developed an extremely miniaturized optical coherence tomography (OCT) needle probe (outer diameter 310 µm) with high sensitivity (108 dB) to enable minimally invasive imaging of cellular structure deep within skeletal muscle. Three-dimensional volumetric images were acquired from ex vivo mouse tissue, examining both healthy and pathological dystrophic muscle. Individual myofibers were visualized as striations in the images. Degradation of cellular structure in necrotic regions was seen as a loss of these striations. Tendon and connective tissue were also visualized. The observed structures were validated against co-registered hematoxylin and eosin (H&E) histology sections. These images of internal cellular structure of skeletal muscle acquired with an OCT needle probe demonstrate the potential of this technique to visualize structure at the microscopic level deep in biological tissue in situ.

Entities: Chemical Disease Species

Keywords: (060.2370) Fiber optics sensors; (170.4500) Optical coherence tomography; (170.6935) Tissue characterization; (230.3990) Micro-optical devices

Year: 2013 PMID： 24466482 PMCID： PMC3891326 DOI： 10.1364/BOE.5.000136

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

52 in total

1. Imaging needle for optical coherence tomography.

Authors: X Li; C Chudoba; T Ko; C Pitris; J G Fujimoto
Journal: Opt Lett Date: 2000-10-15 Impact factor: 3.776

2. En face parametric imaging of tissue birefringence using polarization-sensitive optical coherence tomography.

Authors: Lixin Chin; Xiaojie Yang; Robert A McLaughlin; Peter B Noble; David D Sampson
Journal: J Biomed Opt Date: 2013-06 Impact factor: 3.170

3. Deep-tissue access with confocal fluorescence microendoscopy through hypodermic needles.

Authors: Rajesh S Pillai; Dirk Lorenser; David D Sampson
Journal: Opt Express Date: 2011-04-11 Impact factor: 3.894

4. In situ imaging of lung alveoli with an optical coherence tomography needle probe.

Authors: Bryden C Quirk; Robert A McLaughlin; Andrea Curatolo; Rodney W Kirk; Peter B Noble; David D Sampson
Journal: J Biomed Opt Date: 2011-03 Impact factor: 3.170

5. Identification of muscle necrosis in the mdx mouse model of Duchenne muscular dystrophy using three-dimensional optical coherence tomography.

Authors: Blake R Klyen; Thea Shavlakadze; Hannah G Radley-Crabb; Miranda D Grounds; David D Sampson
Journal: J Biomed Opt Date: 2011-07 Impact factor: 3.170

6. A mouse model for monitoring calpain activity under physiological and pathological conditions.

Authors: Marc Bartoli; Nathalie Bourg; Daniel Stockholm; Fabrice Raynaud; Antony Delevacque; Yang Han; Perrine Borel; Kenza Seddik; Nasser Armande; Isabelle Richard
Journal: J Biol Chem Date: 2006-10-20 Impact factor: 5.157

7. Architecture of healthy and dystrophic muscles detected by optical coherence tomography.

Authors: Richard M Lovering; Sameer B Shah; Stephen J P Pratt; Wei Gong; Yu Chen
Journal: Muscle Nerve Date: 2013-02-04 Impact factor: 3.217

8. Sensitive ultrasonic delineation of steroid treatment in living dystrophic mice with energy-based and entropy-based radio frequency signal processing.

Authors: Kirk D Wallace; Jon N Marsh; Steven L Baldwin; Anne M Connolly; Richard Keeling; Gregory M Lanza; Samuel A Wickline; Michael S Hughes
Journal: IEEE Trans Ultrason Ferroelectr Freq Control Date: 2007-11 Impact factor: 2.725

9. Confocal laser microscopy of dystrophin localization in guinea pig skeletal muscle fibers.

Authors: T Masuda; N Fujimaki; E Ozawa; H Ishikawa
Journal: J Cell Biol Date: 1992-11 Impact factor: 10.539

10. Intrinsic birefringence of glycerinated myofibrils.

Authors: R H Colby
Journal: J Cell Biol Date: 1971-12 Impact factor: 10.539

8 in total

1. Optical coherence tomography can assess skeletal muscle tissue from mouse models of muscular dystrophy by parametric imaging of the attenuation coefficient.

Authors: Blake R Klyen; Loretta Scolaro; Tea Shavlakadze; Miranda D Grounds; David D Sampson
Journal: Biomed Opt Express Date: 2014-03-19 Impact factor: 3.732

2. Three-dimensional optical coherence micro-elastography of skeletal muscle tissue.

Authors: Lixin Chin; Brendan F Kennedy; Kelsey M Kennedy; Philip Wijesinghe; Gavin J Pinniger; Jessica R Terrill; Robert A McLaughlin; David D Sampson
Journal: Biomed Opt Express Date: 2014-08-22 Impact factor: 3.732

3. Resonant reflection spectroscopy of biomolecular arrays in muscle.

Authors: Kevin W Young; Stojan Radic; Evgeny Myslivets; Shawn M O'Connor; Richard L Lieber
Journal: Biophys J Date: 2014-11-18 Impact factor: 4.033

4. Ultra-thin and flexible endoscopy probe for optical coherence tomography based on stepwise transitional core fiber.

Authors: Jangbeom Lee; Yugyeong Chae; Yeh-Chan Ahn; Sucbei Moon
Journal: Biomed Opt Express Date: 2015-04-21 Impact factor: 3.732

5. Molecular imaging needles: dual-modality optical coherence tomography and fluorescence imaging of labeled antibodies deep in tissue.

Authors: Loretta Scolaro; Dirk Lorenser; Wendy-Julie Madore; Rodney W Kirk; Anne S Kramer; George C Yeoh; Nicolas Godbout; David D Sampson; Caroline Boudoux; Robert A McLaughlin
Journal: Biomed Opt Express Date: 2015-04-21 Impact factor: 3.732