In Vivo 3-Dimensional Strain Mapping of the Optic Nerve Head Following Intraocular Pressure Lowering by Trabeculectomy

To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity. Observational case series. Nine patients with primary open-angle glaucoma (POAG) and 3...

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Published in	BMC ophthalmology Vol. 123; no. 6; pp. 1190 - 1200
Main Authors	Girard, Michaël J.A., Beotra, Meghna R., Chin, Khai Sing, Sandhu, Amanjeet, Clemo, Monica, Nikita, Eleni, Kamal, Deborah S., Papadopoulos, Maria, Mari, Jean Martial, Aung, Tin, Strouthidis, Nicholas G.
Format	Journal Article
Language	English
Published	United States Elsevier Inc 01.06.2016 BioMed Central
Subjects	Adult Aged Algorithms Bioengineering Biomechanical Phenomena Female Glaucoma, Open-Angle - diagnostic imaging Glaucoma, Open-Angle - physiopathology Glaucoma, Open-Angle - surgery Humans Imaging Imaging, Three-Dimensional Intraocular Pressure - physiology Life Sciences Male Middle Aged Ophthalmology Optic Disk - diagnostic imaging Optic Disk - physiopathology Optic Nerve Diseases - diagnostic imaging Optic Nerve Diseases - physiopathology Retina - physiopathology Tomography, Optical Coherence Tonometry, Ocular Trabeculectomy Vision Disorders - diagnosis Visual Fields - physiology POAG OCT TE AC LC ONH 3-D IOP adaptive compensation intraocular pressure optical coherence tomography lamina cribrosa trabeculectomy optic nerve head primary open-angle glaucoma 3-dimensional COHERENCE TOMOGRAPHY IMAGES OPEN-ANGLE GLAUCOMA LAMINA-CRIBROSA DISPLACEMENT EYES RISK-FACTORS MECHANICAL STRAIN ENHANCEMENT BIOMECHANICS SCLERA THICKNESS
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ISSN	0161-6420 1549-4713 1471-2415 1549-4713 1471-2415
DOI	10.1016/j.ophtha.2016.02.008

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Abstract	To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity. Observational case series. Nine patients with primary open-angle glaucoma (POAG) and 3 normal controls. The ONHs of 9 subjects with POAG (pre-TE IOP: 25.3±13.9 mmHg; post-TE IOP: 11.8±8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (<21 days) and after (<50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post- and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing. Three-dimensional ONH displacements and strain relief. On average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief (P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief (P < 0.001; high strain relief associated with low retinal sensitivity). We demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity.
AbstractList	To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity. Observational case series. Nine patients with primary open-angle glaucoma (POAG) and 3 normal controls. The ONHs of 9 subjects with POAG (pre-TE IOP: 25.3±13.9 mmHg; post-TE IOP: 11.8±8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (<21 days) and after (<50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post- and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing. Three-dimensional ONH displacements and strain relief. On average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief (P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief (P < 0.001; high strain relief associated with low retinal sensitivity). We demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity. To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity.PURPOSETo map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity.Observational case series.DESIGNObservational case series.Nine patients with primary open-angle glaucoma (POAG) and 3 normal controls.PARTICIPANTSNine patients with primary open-angle glaucoma (POAG) and 3 normal controls.The ONHs of 9 subjects with POAG (pre-TE IOP: 25.3±13.9 mmHg; post-TE IOP: 11.8±8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (<21 days) and after (<50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post- and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing.METHODSThe ONHs of 9 subjects with POAG (pre-TE IOP: 25.3±13.9 mmHg; post-TE IOP: 11.8±8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (<21 days) and after (<50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post- and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing.Three-dimensional ONH displacements and strain relief.MAIN OUTCOME MEASURESThree-dimensional ONH displacements and strain relief.On average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief (P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief (P < 0.001; high strain relief associated with low retinal sensitivity).RESULTSOn average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief (P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief (P < 0.001; high strain relief associated with low retinal sensitivity).We demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity.CONCLUSIONSWe demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity. Purpose To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity. Design Observational case series. Participants Nine patients with primary open-angle glaucoma (POAG) and 3 normal controls. Methods The ONHs of 9 subjects with POAG (pre-TE IOP: 25.3±13.9 mmHg; post-TE IOP: 11.8±8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (<21 days) and after (<50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post- and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing. Main Outcome Measures Three-dimensional ONH displacements and strain relief. Results On average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief ( P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief ( P < 0.001; high strain relief associated with low retinal sensitivity). Conclusions We demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity. Purpose: To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish associations between ONH strain and retinal sensitivity.Design: Observational case series.Participants: Nine patients with primary open-angle glaucoma (POAG) and 3 normal controls.Methods: The ONHs of 9 subjects with POAG (pre-TE IOP: 25.3 +/- 13.9 mmHg; post-TE IOP: 11.8 +/- 8.6 mmHg) were imaged (1 eye per subject) using optical coherence tomography (OCT) (Heidelberg Spectralis, Heidelberg Engineering GmbH, Heidelberg, Germany) before (< 21 days) and after (< 50 days) TE. The imaging protocol was repeated for 3 controls in whom IOP was not altered. In each post-TE OCT volume, 4 tissues were manually segmented (prelamina, choroid, sclera, and lamina cribrosa [LC]). For each ONH, a 3D tracking algorithm was applied to both post-and pre-TE OCT volumes to extract IOP-induced 3D displacements at segmented nodes. Displacements were filtered, smoothed, and processed to extract 3D strain relief (the amount of tissue deformation relieved after TE). Strain relief was compared with measures of retinal sensitivity from visual field testing.Main Outcome Measures: Three-dimensional ONH displacements and strain relief.Results: On average, strain relief (averaged or effective component) in the glaucoma ONHs (8.6%) due to TE was higher than that measured in the normal controls (1.07%). We found no associations between the magnitude of IOP decrease and the LC strain relief (P > 0.05), suggesting biomechanical variability across subjects. The LC displaced posteriorly, anteriorly, or not at all. Furthermore, we found linear associations between retinal sensitivity and LC effective strain relief (P < 0.001; high strain relief associated with low retinal sensitivity).Conclusions: We demonstrate that ONH displacements and strains can be measured in vivo and that TE can relieve ONH strains. Our data suggest a wide variability in ONH biomechanics in the subjects examined in this study. We further demonstrate associations between LC effective strain relief and retinal sensitivity.
Author	Nikita, Eleni Beotra, Meghna R. Clemo, Monica Strouthidis, Nicholas G. Sandhu, Amanjeet Girard, Michaël J.A. Kamal, Deborah S. Papadopoulos, Maria Chin, Khai Sing Mari, Jean Martial Aung, Tin
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Copyright	2016 American Academy of Ophthalmology American Academy of Ophthalmology Copyright © 2016 American Academy of Ophthalmology. Published by Elsevier Inc. All rights reserved. Distributed under a Creative Commons Attribution 4.0 International License
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Keywords	POAG OCT TE AC LC ONH 3-D IOP adaptive compensation intraocular pressure optical coherence tomography lamina cribrosa trabeculectomy optic nerve head primary open-angle glaucoma 3-dimensional COHERENCE TOMOGRAPHY IMAGES OPEN-ANGLE GLAUCOMA LAMINA-CRIBROSA DISPLACEMENT EYES RISK-FACTORS MECHANICAL STRAIN ENHANCEMENT BIOMECHANICS SCLERA THICKNESS
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PublicationTitleAlternate	Ophthalmology
PublicationYear	2016
Publisher	Elsevier Inc BioMed Central
Publisher_xml	– name: Elsevier Inc – name: BioMed Central
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Snippet	To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish... Purpose To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to... To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to establish... Purpose: To map the 3-dimensional (3D) strain of the optic nerve head (ONH) in vivo after intraocular pressure (IOP) lowering by trabeculectomy (TE) and to...
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SubjectTerms	Adult Aged Algorithms Bioengineering Biomechanical Phenomena Female Glaucoma, Open-Angle - diagnostic imaging Glaucoma, Open-Angle - physiopathology Glaucoma, Open-Angle - surgery Humans Imaging Imaging, Three-Dimensional Intraocular Pressure - physiology Life Sciences Male Middle Aged Ophthalmology Optic Disk - diagnostic imaging Optic Disk - physiopathology Optic Nerve Diseases - diagnostic imaging Optic Nerve Diseases - physiopathology Retina - physiopathology Tomography, Optical Coherence Tonometry, Ocular Trabeculectomy Vision Disorders - diagnosis Visual Fields - physiology
Title	In Vivo 3-Dimensional Strain Mapping of the Optic Nerve Head Following Intraocular Pressure Lowering by Trabeculectomy
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