A Large-Scale Computational Analysis of Corneal Structural Response and Ectasia Risk in Myopic Laser Refractive Surgery
To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial. A finite element modeling study was performed using retrospective Scheimpflug tomography data from 40 eyes of 40 patients. LASIK and PRK were simulated with varied myop...
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| Published in | Transactions of the American Ophthalmological Society Vol. 114; p. T1 |
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| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
United States
The American Ophthalmological Society
01.08.2016
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| Subjects | |
| Online Access | Get full text |
| ISSN | 1545-6110 0065-9533 1545-6110 |
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| Abstract | To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.
A finite element modeling study was performed using retrospective Scheimpflug tomography data from 40 eyes of 40 patients. LASIK and PRK were simulated with varied myopic ablation profiles and flap thickness parameters across eyes from LASIK candidates, patients disqualified for LASIK, subjects with atypical topography, and keratoconus subjects in 280 simulations. Finite element analysis output was then interrogated to extract several risk and outcome variables. We tested the hypothesis that strain is greater in known at-risk eyes than in normal eyes, evaluated the ability of a candidate strain variable to differentiate eyes that were empirically disqualified as LASIK candidates, and compared the performance of common risk variables as predictors of this novel susceptibility marker across multiple virtual subjects and surgeries.
A candidate susceptibility metric that expressed mean strains across the anterior residual stromal bed was significantly higher in eyes with confirmed ectatic predisposition in preoperative and all postoperative cases (P≤.003). The strain metric was effective at differentiating normal and at-risk eyes (area under receiver operating characteristic curve ≥ 0.83, P≤.002), was highly correlated to thickness-based risk metrics (as high as R(2) = 95%, P<.001 for the percent of stromal tissue altered (PSTA)), and predicted large portions of the variance in predicted refractive response to surgery (R(2) = 57%, P<.001).
This study represents the first large-scale 3-dimensional structural analysis of ectasia risk and provides a novel biomechanical construct for expressing structural risk in refractive surgery. Mechanical strain is an effective marker of known ectasia risk and correlates to predicted refractive error after myopic photoablative surgery. |
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| AbstractList | To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.
A finite element modeling study was performed using retrospective Scheimpflug tomography data from 40 eyes of 40 patients. LASIK and PRK were simulated with varied myopic ablation profiles and flap thickness parameters across eyes from LASIK candidates, patients disqualified for LASIK, subjects with atypical topography, and keratoconus subjects in 280 simulations. Finite element analysis output was then interrogated to extract several risk and outcome variables. We tested the hypothesis that strain is greater in known at-risk eyes than in normal eyes, evaluated the ability of a candidate strain variable to differentiate eyes that were empirically disqualified as LASIK candidates, and compared the performance of common risk variables as predictors of this novel susceptibility marker across multiple virtual subjects and surgeries.
A candidate susceptibility metric that expressed mean strains across the anterior residual stromal bed was significantly higher in eyes with confirmed ectatic predisposition in preoperative and all postoperative cases (P≤.003). The strain metric was effective at differentiating normal and at-risk eyes (area under receiver operating characteristic curve ≥ 0.83, P≤.002), was highly correlated to thickness-based risk metrics (as high as R(2) = 95%, P<.001 for the percent of stromal tissue altered (PSTA)), and predicted large portions of the variance in predicted refractive response to surgery (R(2) = 57%, P<.001).
This study represents the first large-scale 3-dimensional structural analysis of ectasia risk and provides a novel biomechanical construct for expressing structural risk in refractive surgery. Mechanical strain is an effective marker of known ectasia risk and correlates to predicted refractive error after myopic photoablative surgery. To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.PURPOSETo investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.A finite element modeling study was performed using retrospective Scheimpflug tomography data from 40 eyes of 40 patients. LASIK and PRK were simulated with varied myopic ablation profiles and flap thickness parameters across eyes from LASIK candidates, patients disqualified for LASIK, subjects with atypical topography, and keratoconus subjects in 280 simulations. Finite element analysis output was then interrogated to extract several risk and outcome variables. We tested the hypothesis that strain is greater in known at-risk eyes than in normal eyes, evaluated the ability of a candidate strain variable to differentiate eyes that were empirically disqualified as LASIK candidates, and compared the performance of common risk variables as predictors of this novel susceptibility marker across multiple virtual subjects and surgeries.METHODSA finite element modeling study was performed using retrospective Scheimpflug tomography data from 40 eyes of 40 patients. LASIK and PRK were simulated with varied myopic ablation profiles and flap thickness parameters across eyes from LASIK candidates, patients disqualified for LASIK, subjects with atypical topography, and keratoconus subjects in 280 simulations. Finite element analysis output was then interrogated to extract several risk and outcome variables. We tested the hypothesis that strain is greater in known at-risk eyes than in normal eyes, evaluated the ability of a candidate strain variable to differentiate eyes that were empirically disqualified as LASIK candidates, and compared the performance of common risk variables as predictors of this novel susceptibility marker across multiple virtual subjects and surgeries.A candidate susceptibility metric that expressed mean strains across the anterior residual stromal bed was significantly higher in eyes with confirmed ectatic predisposition in preoperative and all postoperative cases (P≤.003). The strain metric was effective at differentiating normal and at-risk eyes (area under receiver operating characteristic curve ≥ 0.83, P≤.002), was highly correlated to thickness-based risk metrics (as high as R(2) = 95%, P<.001 for the percent of stromal tissue altered (PSTA)), and predicted large portions of the variance in predicted refractive response to surgery (R(2) = 57%, P<.001).RESULTSA candidate susceptibility metric that expressed mean strains across the anterior residual stromal bed was significantly higher in eyes with confirmed ectatic predisposition in preoperative and all postoperative cases (P≤.003). The strain metric was effective at differentiating normal and at-risk eyes (area under receiver operating characteristic curve ≥ 0.83, P≤.002), was highly correlated to thickness-based risk metrics (as high as R(2) = 95%, P<.001 for the percent of stromal tissue altered (PSTA)), and predicted large portions of the variance in predicted refractive response to surgery (R(2) = 57%, P<.001).This study represents the first large-scale 3-dimensional structural analysis of ectasia risk and provides a novel biomechanical construct for expressing structural risk in refractive surgery. Mechanical strain is an effective marker of known ectasia risk and correlates to predicted refractive error after myopic photoablative surgery.CONCLUSIONSThis study represents the first large-scale 3-dimensional structural analysis of ectasia risk and provides a novel biomechanical construct for expressing structural risk in refractive surgery. Mechanical strain is an effective marker of known ectasia risk and correlates to predicted refractive error after myopic photoablative surgery. |
| Author | Seven, Ibrahim Dupps, Jr, William Joseph |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/27630372$$D View this record in MEDLINE/PubMed |
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| Notes | ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 This work was performed at the Cole Eye Institute and in the Ocular Biomechanics and Imaging Laboratory at Cleveland Clinic |
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| References | 30947852 - J Cataract Refract Surg. 2019 Apr;45(4):391-393 |
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| Snippet | To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.
A finite element modeling... To investigate biomechanical strain as a structural susceptibility metric for corneal ectasia in a large-scale computational trial.PURPOSETo investigate... |
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| SubjectTerms | Cornea - pathology Cornea - surgery Corneal Topography - methods Dilatation, Pathologic - diagnosis Female Finite Element Analysis Follow-Up Studies Humans Keratomileusis, Laser In Situ - methods Male Myopia - diagnosis Myopia - physiopathology Myopia - surgery Postoperative Period Refraction, Ocular Retrospective Studies Risk Factors |
| Title | A Large-Scale Computational Analysis of Corneal Structural Response and Ectasia Risk in Myopic Laser Refractive Surgery |
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