RT Journal Article
SR Electronic
T1 Spectral domain optical coherence tomography imaging of the aqueous outflow structures in normal participants of the EPIC-Norfolk Eye Study
JF British Journal of Ophthalmology
JO Br J Ophthalmol
FD BMJ Publishing Group Ltd.
SP 189
OP 195
DO 10.1136/bjophthalmol-2012-302147
VO 97
IS 2
A1 Alexander C Day
A1 David F Garway-Heath
A1 David C Broadway
A1 Yuzhen Jiang
A1 Shabina Hayat
A1 Nichola Dalzell
A1 Kay-Tee Khaw
A1 Paul J Foster
YR 2013
UL http://bjo.bmj.com/content/97/2/189.abstract
AB Purpose To measure the dimensions of aqueous outflow structures and to investigate associations with intraocular pressure (IOP) and ocular biometry parameters in an older British population. Method Fifty-two participants from the European Prospective Investigation of Cancer-Norfolk eye study underwent imaging using the Heidelberg Spectralis optical coherence tomographer with an anterior segment module. Pseudophakic participants and those known or suspected to have glaucoma were excluded, leaving 46 participants for analysis. Schwalbe's line (SL), scleral spur (SS), Schlemm's canal (SC) diameter and the trabecular meshwork cross-sectional area (TM cross-sectional area (CSA)) were identified and traced using ImageJ software. IOP was measured using the Ocular Response Analyser. Ocular biometry was measured by partial coherence interferometry. Results The mean (SD) subject age was 65.7 years (5.6). The SL and SS were identifiable in all nasal and temporal scans. The mean SL–SS distance was 800 μm (104) nasally and 808 μm (102) temporally. Repeatability of SS–SL, SS–SC, SC and TM CSA was good to excellent, and reproducibility fair to good. Nasal SL–SS distance was inversely associated with anterior chamber depth (ACD) (p=0.007, −116 μm per mm ACD, R2=0.18). Multiple linear regression showed nasal TM CSA was significantly associated with age and IOP (age: p=0.025, 0.007 mm2 per decade of age; IOP: p=0.029, −0.0012 mm2 per mm Hg, R2=0.23). Conclusions Aqueous outflow structures can be measured by optical coherence tomography, and their dimensions vary significantly with ocular biometric characteristics and IOP. Further investigation is required to determine associations between outflow structure sizes in different populations and pathologies, including ocular hypertension and glaucoma.