Your search keyword '"Chew, Paul T."' showing total 5 results

1. Analysis of Anterior Segment Dynamics Using Anterior Segment Optical Coherence Tomography Before and After Laser Peripheral Iridotomy.

Author

Ce Zheng, Guzman, Celeste P., Cheung, Carol Y., Yingke He, Friedman, David S., Sim-Heng Ong, Narayanaswamy, Arun K., Chew, Paul T., Perera, Shamira A., and Tin Aung

Published

2013

2. Cataract Surgery After Trabeculectomy.

Author

Husain, Rahat, Shen Liang, Foster, Paul J., Gazzard, Gus, Bunce, Catey, Chew, Paul T. K., Oen, Francis T. S., Khaw, Peng T., Seah, Steve K. L., and Aung, Tin

Abstract

Objective: To determine whether the timing of cataract surgery after trabeculectomy has an effect on trabeculectomy function in terms of intraocular pressure control. Methods: This was a cohort study nested within a randomized clinical trial. There were 235 participants with glaucoma who had a single previous trabeculectomy augmented with either intraoperative 5-fluorouracil or placebo. Cataract surgery with intraocular lens implantation was performed on participants judged to have significant lens opacity. Cox regression was performed to evaluate the effect of time between trabeculectomy and cataract surgery on the time to trabeculectomy failure, after adjusting for other relevant risk factors. The main outcome measure was time to failure of trabeculectomy, defined as an intraocular pressure of greater than 21mmHg. Results: Of the 235 participants, 124 (52.7%) underwent subsequent cataract surgery. The median time from trabeculectomy to cataract surgery for these patients was 21.7 months (range, 4.6-81.9 months). The median follow-up period was 60 months (range, 28-84 months) for the cataract surgery group and 48 months (range, 12-84 months) for the non-cataract surgery group. Cox regression showed that the time from trabeculectomy to cataract surgery was significantly associated with time to trabeculectomy failure (hazard ratio, 1.73 [95% CI, 1.05-2.85]; P=.03). The adjusted declining hazard ratios for risk of subsequent trabeculectomy failure when cataract surgery was performed 6 months, 1 year, and 2 years after trabeculectomy were 3.00 (95% CI, 1.11- 8.14), 1.73 (95% CI, 1.05-2.85), and 1.32 (95% CI, 1.02- 1.69), respectively. Conclusions: Cataract surgery after trabeculectomy increases the risk of trabeculectomy failure, and this risk is increased if the time between trabeculectomy and cataract surgery is shorter. [ABSTRACT FROM AUTHOR]

Published

2012

3. Effect of Trabeculectomy on Lens Opacities in an East Asian Population.

Author

Husain, Rahat, Tin Aung, Gazzard, Gus, Foster, Paul J., Devereux, Joe G., Chew, Paul T. K., Oen, Francis T. S., Khaw, Peng T., and Seah, Steve K. L.

Abstract

Objective: To examine the progression of lens opacity in Asian people after trabeculectomy and determine associated risk factors. Methods: This was an observational case series of 243 people aged 36 to 82 years. Trabeculectomy was performed on 1 eye of each subject. Lens opacity was measured yearly using the Lens Opacification Classification System III. The main outcome measure was worsening of lens opacity defined as an increase of 2 or more Lens Opacification Classification System III units in any of the 3 lens regions, nuclear, cortical, and posterior subcapsular. Risk of progression was evaluated using logistic regression models. Results: Data for 177 people were analyzed. One hundred seventeen (66%) of 177 subjects showed progression in opacity in any lens region at 3 years. Seventy-seven (66%) of 117 of those who progressed did so during the first year. Of these, 63 (82%) of 77 had lens opacity in the posterior subcapsular region. Factors associated with progression of posterior-subcapsular lens opacity at 1 year were diabetes (odds ratio, 2.4; 95% confidence interval, 1.0-5.4), use of antiglaucoma medication, dosage of topical steroid postoperatively, and being operated on by a trainee surgeon (odds ratio, 2.3; 95% confidence interval, 1.0-5.2). Conclusions: Trabeculectomy is associated with progression of lens opacity predominantly in the posterior subcapsular region. Modification of risk factors such as postoperative steroid use may delay progression. [ABSTRACT FROM AUTHOR]

Published

2006

4. The Severity and Spatial Distribution of Visual Field Defects in Primary Glaucoma: A Comparison of Primary Open-Angle Glaucoma and Primary Angle-Closure Glaucoma.

Author

Gazzard, Gus, Foster, Paul J., Viswanathan, Ananth C., Devereux, Joe G., Oen, Francis T. S., Chew, Paul T. K., Khaw, Peng T., and Seah, Steve K. L.

Subjects

VISION disorders, GLAUCOMA

Abstract

Objective: To compare the characteristics of visual field defects in primary angle-closure glaucoma (PACG) and primary open-angle glaucoma (POAG). Methods: Subjects with primary glaucoma aged 30 years and older were prospectively considered for inclusion. Automated static white-on-white perimetry was performed. A minimum of 2 reliable tests was required with a mean deviation (MD) within 2 dB on 2 tests. Subjects with previous symptomatic angle-closure, normaltension glaucoma, visually significant cataract, or previous intraocular surgery were excluded. Results: Of 234 subjects assessed, 129 had POAG, and 105 had PACG. The MDs (POAG group, -13.3 dB; PACG group, -18.0 dB) indicated more severe visual loss in subjects with PACG. In subjects with POAG, the superior hemifield was more severely affected than the inferior. This was less pronounced in subjects with PACG. Following stratification by MD, the difference between hemifields was marked in the mild (-10 dB≤MD) and moderate (-20 dB≤MD<-10 dB) subgroups but was not present in the severe (MD<-20 dB) subgroup. We detected differences between POAG and PACG in retinal sensitivity between the superior and inferior hemifields, independent of severity of damage. Conclusions: The pattern of visual field loss was different in the 2 diseases. This may give insight into the pattern of visual loss in predominantly pressure-dependent glaucomatous optic neuropathy. [ABSTRACT FROM AUTHOR]

Published

2002

5. Analysis of anterior segment dynamics using anterior segment optical coherence tomography before and after laser peripheral iridotomy.

Author

Zheng C, Guzman CP, Cheung CY, He Y, Friedman DS, Ong SH, Narayanaswamy AK, Chew PT, Perera SA, and Aung T

Subjects

Adult, Aged, Anterior Chamber pathology, Axial Length, Eye pathology, Biometry, Corneal Pachymetry, Female, Glaucoma, Angle-Closure physiopathology, Humans, Intraocular Pressure physiology, Male, Middle Aged, Prospective Studies, Tomography, Optical Coherence, Tonometry, Ocular, Visual Acuity physiology, Glaucoma, Angle-Closure surgery, Iridectomy, Iris surgery, Laser Therapy methods, Lasers, Solid-State therapeutic use, Pupil physiology

Abstract

Objective: To evaluate changes in the speed of pupil constriction and in anterior segment parameters after laser peripheral iridotomy (LPI) in patients with angle closure using anterior segment optical coherence tomography., Methods: In this prospective observational study, videos of pupil and anterior segment changes in response to illumination were captured with real-time video recording using anterior segment optical coherence tomography and were analyzed frame by frame before and after LPI. Customized software was used to measure the speed of pupil constriction and changes in anterior chamber depth and anterior chamber area, as well as iris thickness at 750 μm from the scleral spur, at the sphincter muscle region (0.75 mm from the pupillary margin), and at the mid-iris location (half the distance between the scleral spur and the pupillary margin). Pupil diameter, angle opening distance, and trabecular-iris space area at 500 μm from the scleral spur were determined. The speed of pupil constriction was defined as the rate of pupil diameter change in response to illumination., Results: Twenty-nine patients were included. Most were Chinese (26 of 29 [90%]) and female (18 of 29 [62%]). The anterior chamber area, angle opening distance at 500 μm from the scleral spur, and trabecular-iris space area at 500 μm from the scleral spur were significantly higher after LPI (P < .001). A significant increase was observed in the speed of pupil constriction after LPI (P < .005). In response to illumination, the rate of change in iris thickness at the sphincter muscle region and at 750 μm from the scleral spur was faster after LPI (P < .05). Similarly, an increase was observed in the speed of change of angle-opening distance at 500 μm from the scleral spur in response to illumination after LPI (P < .05)., Conclusions: In patients with angle closure, changes in dynamic iridopupillary behavior are observed after LPI. The speed of pupillary constriction is faster after LPI.

Published

2013