Your search keyword '"Jan NJ"' showing total 5 results

1. Polarized light microscopy for 3-dimensional mapping of collagen fiber architecture in ocular tissues.

Author

Yang B, Jan NJ, Brazile B, Voorhees A, Lathrop KL, and Sigal IA

Subjects

Animals, Chickens, Humans, Optical Phenomena, Sheep, Tendons diagnostic imaging, Tendons metabolism, Collagen metabolism, Cornea diagnostic imaging, Cornea metabolism, Imaging, Three-Dimensional, Microscopy, Polarization, Sclera diagnostic imaging, Sclera metabolism

Abstract

Collagen fibers play a central role in normal eye mechanics and pathology. In ocular tissues, collagen fibers exhibit a complex 3-dimensional (3D) fiber orientation, with both in-plane (IP) and out-of-plane (OP) orientations. Imaging techniques traditionally applied to the study of ocular tissues only quantify IP fiber orientation, providing little information on OP fiber orientation. Accurate description of the complex 3D fiber microstructures of the eye requires quantifying full 3D fiber orientation. Herein, we present 3dPLM, a technique based on polarized light microscopy developed to quantify both IP and OP collagen fiber orientations of ocular tissues. The performance of 3dPLM was examined by simulation and experimental verification and validation. The experiments demonstrated an excellent agreement between extracted and true 3D fiber orientation. Both IP and OP fiber orientations can be extracted from the sclera and the cornea, providing previously unavailable quantitative 3D measures and insight into the tissue microarchitecture. Together, the results demonstrate that 3dPLM is a powerful imaging technique for the analysis of ocular tissues., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

2. Crimp around the globe; patterns of collagen crimp across the corneoscleral shell.

Author

Jan NJ, Brazile BL, Hu D, Grube G, Wallace J, Gogola A, and Sigal IA

Subjects

Animals, Biomechanical Phenomena, Microscopy, Polarization, Sheep, Collagen Type I metabolism, Cornea metabolism, Sclera metabolism

Abstract

Our goal was to systematically quantify the collagen crimp morphology around the corneoscleral shell, and test the hypothesis that collagen crimp is not uniform over the globe. Axial longitudinal cryosections (30 μm) of three sheep eyes, fixed at 0 mmHg IOP, were imaged using polarized light microscopy to quantify the local collagen in 8 regions: two corneal (central and peripheral) and six scleral (limbus, anterior-equatorial, equatorial, posterior-equatorial, posterior and peripapillary). Collagen crimp period (length of one wave), tortuosity (path length divided by end-to-end length), waviness (SD of orientation), amplitude (half the peak to trough distance), and conformity (width of contiguous similarly oriented bundles) were measured in each region. Measurements were obtained on 8216 collagen fiber bundles. When pooling measurements across the whole eye globe, the median crimp values were: 23.9 μm period, 13.2 μm conformity, 0.63 μm amplitude, 1.006 tortuosity, and 12.7° waviness. However, all parameters varied significantly across the globe. Median bundle periods in the central cornea, limbus, and peripapillary sclera (PPS) were 14.1 μm, 29.5 μm, and 22.9 μm, respectively. Median conformities were 20.8 μm, 14.5 μm, and 15.1 μm, respectively. Median tortuosities were 1.005, 1.007, and 1.007, respectively. Median waviness' were 11.4°, 13.2°, and 13.2°, respectively. Median amplitudes were 0.35 μm, 0.87 μm, and 0.65 μm, respectively. All parameters varied significantly across the globe. All regions differed significantly from one another on at least one parameter. Regions with small periods had large conformities, and bundles with high tortuosity had high waviness and amplitude. Waviness, tortuosity, and amplitude, associated with nonlinear biomechanical behavior, exhibited "double hump" distributions, whereas period and conformity, representing tissue organization, were substantially different between sclera and cornea. Though the biomechanical implications and origin of the patterns observed remain unclear, our findings of well-defined patterns of collagen crimp across the corneoscleral shell, consistent between eyes, support the existence of mechanisms that regulate collagen characteristics at the regional or smaller levels. These results are experimental data necessary for more realistic models of ocular biomechanics and remodeling., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

3. Spatial Patterns and Age-Related Changes of the Collagen Crimp in the Human Cornea and Sclera.

Author

Gogola A, Jan NJ, Brazile B, Lam P, Lathrop KL, Chan KC, and Sigal IA

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Child, Child, Preschool, Female, Healthy Volunteers, Humans, Infant, Infant, Newborn, Male, Microscopy, Polarization, Middle Aged, Tissue Donors, Aging physiology, Collagen metabolism, Cornea metabolism, Sclera metabolism

Abstract

Purpose: Collagen is the main load-bearing component of the eye, and collagen crimp is a critical determinant of tissue mechanical behavior. We test the hypothesis that collagen crimp morphology varies over the human cornea and sclera and with age., Methods: We analyzed 42 axial whole-globe sections from 20 normal eyes of 20 human donors, ranging in age from 0.08 (1 month) to 97 years. The sections were imaged using polarized light microscopy to obtain μm-scale fiber bundle/lamellae orientation from two corneal and six scleral regions. Crimp morphology was quantified through waviness, tortuosity, and amplitude., Results: Whole-globe median waviness, tortuosity, and amplitude were 0.127 radians, 1.002, and 0.273 μm, respectively. These parameters, however, were not uniform over the globe, instead exhibiting distinct, consistent patterns. All crimp parameters decreased significantly with age, with significantly different age-related decreases between regions. The crimp morphology of the limbus changed the most drastically with age, such that it had the largest crimp in neonates, and among the smallest in the elderly., Conclusions: Age-related decreases in crimp parameters are likely one of the mechanisms underlying age-related stiffening of the sclera and cornea, potentially influencing sensitivity to IOP. Further work is needed to determine the biomechanical implications of the crimp patterns observed. The comparatively large changes in the crimp morphology of the limbus, especially in the early years of life, suggest that crimp in this region may play a role in eye development, although the exact nature of this is unclear.

Published

2018

4. Magic angle-enhanced MRI of fibrous microstructures in sclera and cornea with and without intraocular pressure loading.

Author

Ho LC, Sigal IA, Jan NJ, Squires A, Tse Z, Wu EX, Kim SG, Schuman JS, and Chan KC

Subjects

Animals, Cornea ultrastructure, Humans, Models, Animal, Models, Biological, Sclera ultrastructure, Sheep, Collagen ultrastructure, Cornea physiology, Intraocular Pressure physiology, Magnetic Resonance Imaging methods, Sclera physiology

Abstract

Purpose: The structure and biomechanics of the sclera and cornea are central to several eye diseases such as glaucoma and myopia. However, their roles remain unclear, partly because of limited noninvasive techniques to assess their fibrous microstructures globally, longitudinally, and quantitatively. We hypothesized that magic angle-enhanced magnetic resonance imaging (MRI) can reveal the structural details of the corneoscleral shell and their changes upon intraocular pressure (IOP) elevation., Methods: Seven ovine eyes were extracted and fixed at IOP = 50 mm Hg to mimic ocular hypertension, and another 11 eyes were unpressurized. The sclera and cornea were scanned at different angular orientations relative to the main magnetic field inside a 9.4-Tesla MRI scanner. Relative MRI signal intensities and intrinsic transverse relaxation times (T2 and T2*) were determined to quantify the magic angle effect on the corneoscleral shells. Three loaded and eight unloaded tendon samples were scanned as controls., Results: At magic angle, high-resolution MRI revealed distinct scleral and corneal lamellar fibers, and light/dark bands indicative of collagen fiber crimps in the sclera and tendon. Magic angle enhancement effect was the strongest in tendon and the least strong in cornea. Loaded sclera, cornea, and tendon possessed significantly higher T2 and T2* than unloaded tissues at magic angle., Conclusions: Magic angle-enhanced MRI can detect ocular fibrous microstructures without contrast agents or coatings and can reveal their MR tissue property changes with IOP loading. This technique may open up new avenues for assessment of the biomechanical and biochemical properties of ocular tissues in aging and in diseases involving the corneoscleral shell., (Copyright 2014 The Association for Research in Vision and Ophthalmology, Inc.)

Published

2014

5. Characterisation of Schlemm's canal cross-sectional area.

Author

Kagemann L, Nevins JE, Jan NJ, Wollstein G, Ishikawa H, Kagemann J, Sigal IA, Nadler Z, Ling Y, and Schuman JS

Subjects

Adult, Aqueous Humor physiology, Female, Healthy Volunteers, Humans, Male, Middle Aged, Tomography, Optical Coherence, Young Adult, Anatomy, Cross-Sectional, Cornea anatomy & histology, Limbus Corneae anatomy & histology, Sclera anatomy & histology

Abstract

Purpose: To compare three methods of Schlemm's canal (SC) cross-sectional area (CSA) measurement., Methods: Ten eyes (10 healthy volunteers) were imaged three times using spectral-domain optical coherence tomography (Cirrus HD-OCT, Zeiss, Dublin, California, USA). Aqueous outflow vascular structures and SC collector channel ostia were used as landmarks to identify a reference location within the limbus. SC CSA was assessed within a 1 mm segment (±15 frames of the reference, 31 frames in all) by three techniques. (1) Using a random number table, SC CSA in five random frames from the set of 31 surrounding the reference were measured and averaged. (2) The most easily visualised SC location (subjective) was measured, and (3) SC CSA was measured in all 31 consecutive B-scans, and averaged. (comprehensive average, gold standard). Subjective and random CSAs were compared with the comprehensive by general estimating equation modelling, and structural equation modelling quantified agreement., Results: The average from five random locations (4175±1045 µm(2)) was not significantly different than that obtained from the gold standard comprehensive assessment (4064±1308 µm(2), p=0.6537). Subjectively located SC CSA (7614±2162 µm(2)) was significantly larger than the comprehensive gold standard SC CSA (p<0.0001). The average of five random frames produced significantly less bias than did subjective location, yielding a calibration line crossing the 'no-bias' line., Discussion: Subjectively located SC CSA measurements produce high estimates of SC CSA. SC assessed by measuring five random locations estimate CSA was similar to the gold standard estimate., (Published by the BMJ Publishing Group Limited. For permission to use (where not already granted under a licence) please go to http://group.bmj.com/group/rights-licensing/permissions.)

Published

2014