Post on 14-Dec-2015
A Comparison between Fluorescein Angiography and
Optical Coherence Tomography Findings in Patients with
Clinically Significant Macular Edema
KoriAnne Elkins Galler, M.D.
Resident’s Day
May 30th, 2008
Introduction
• Macular edema is the most common cause of decreased visual acuity and quality of life in diabetic patients
• Slit lamp biomicroscopy is the gold standard for diagnosis based on the ETDRS criteria
• Laser photocoagulation is the mainstay of treatment for CSME
• Vascular leakage can be qualitatively measured with fluorescein angiography (FA)– Provides guidance for application of focal laser
– Leakage can be present without clinical evidence of edema
• Optical coherence tomography (OCT) is a non-invasive way to calculate macular thickening and demonstrate retinal swelling
Introduction
• Several authors have established a correlation between FA leakage and abnormal macular thickness or retinal swelling on OCT
• However, these studies have several limitations – Timing of FA and OCT data– Inclusion of only horizontal and vertical meridians for
comparison
Introduction
Otani T, Kishi S. Correlation between Optical Coherence Tomography and Fluorescein Angiography Findings in Diabetic Macular Edema. Ophthalmology 2007;114 Kang SW, Park CY, Ham DI: The correlation between fluorescein angiographic and optical coherence tomographic features in clinically significant diabetic macular edema. Am J Ophthalmol 2004;137:313–322. Özdek SC, Erdinç MA, Gürelik G, Aydın B, Bahçeci U, Hasanreisog B. Optical Coherence Tomographic Assessment of Diabetic Macular Edema: Comparison with Fluorescein Angiographic and Clinical Findings. Ophthalmologica 2005;219:86–92
• OCT has the potential to improve clinic efficiency
• In some places, OCT is being used in placed of FA
• In order for OCT to supplant FA, it must be able to reliably detect leakage and provide valuable information for treatment and follow-up
Introduction
Purpose• To evaluate the correlation between
fluorescein leakage and optical coherence tomography (OCT) abnormalities in diabetic patients with clinically significant macular edema (CSME)
Methods
• Retrospective review of 74 eyes of 48 patients with a diagnosis of CSME
• All patients that had fluorescein angiography (FA) and OCT testing on the same day were reviewed
Methods
• Treatment-naïve and treated patients (laser, intravitreal injection, or vitrectomy) were included in this study
Methods
• Fluorescein angiograms were graded by a single physician in a masked fashion
• OCTs were read independently of the FAs by a second masked physician
Methods: Fluorescein Angiography
• For each eye, digitized early-phase and late-phase FA images were reviewed– Early: 1-2 minutes post-injection– Late: 5-10 minutes post-injection
• Images were overlain with a modified ETDRS grid and type of leakage recorded
Methods: Fluorescein Angiography
Grades of FA leakage
FA Leakage Types
Grade 1 Normal
Grade 2 Focal
Grade 3 Mixed Focal & Diffuse
Grade 4 Diffuse
Grade 5 Cystoid Macular Edema
Methods: OCT Analysis
• OCT was performed on a Zeiss OCT3– 6.0-mm scans in 6 meridians (every 30
degrees) for each study eye
• A digitized grid was created for the radial OCT scans to correspond to the same areas as the ETDRS grid
Methods: OCT Analysis
Methods: OCT Types
OCT Abnormality Types
Type 1 Swelling without cysts
Type 2 Swelling with cysts
Type 3ANeurosensory detachment without VMT
Type 3BNeurosensory detachment with VMT
Methods: Comparison of FA’s to OCT’s
Methods: OCT Map Analysis
• The standard macular thickness map was used to record the thickness in 9 standard subfields
• Values of > 250 microns for central foveal thickness and > 300 microns for other subfields were considered abnormal
Results: Baseline Characteristics
Number Percentage
Men 23 47.9
Women 25 52.1
Age 58 (Range 39-75)
DM I 6 13.0
DM II 42 87.0
Treatment-naïve eyes
46 64.8
74 eyes of 48 patients the study
Results: Patterns of Leakage
Normal Focal Mixed Diffuse CME
FA/OCT Correlation
Only 42% of zone-by-zone comparisons had both an abnormal FA and OCT
74 Eyes x 9 zones per eye = 666 zones
Results: Abnormal OCT’s by FA Grade
Concordance of FA & OCT
• A total of 666 comparisons were made between FA and OCT zones– 386 (58%) showed consistent findings – 233 (35%) had an abnormal FA with a normal
OCT in all 3 subscans– 47 (7.1%) resulted in a normal FA with an
abnormal OCT in at least one scan
• Cohen’s kappa of 0.1673 (poorly concordant)
Macular Thickness Correlation & Distribution
FA Leakage PatternAbnormal OCT Thickness Measurements
Inner + outer zones (67 eyes) 46 eyes (64.8 %)
Inner zone only (2 eyes) 1 eye (50%)
Outer zone only (2 eyes) 0 eyes (0 %)
No leakage (0 eyes) 0 eyes (0 %)
Discussion• Of the 280 (42%) comparisons that resulted
in a mis-match between FA and OCT – 233 (35%) with abnormal FA and a normal OCT
– Only 47 (7.1%) instances with a normal FA but some abnormality detected on the OCT
• Additionally, in 35% of patients OCT thickness measurements were normal despite FA leakage
• This suggests that there is a large subset of patients that will have leakage detected on FA but no comparable OCT changes or increased macular thickness
Discussion
Discussion
• Two possibilities to account for this difference– First, these patients may still have a relatively
healthy retinal pigment epithelium • Able to pump out the additional fluid without
leading to retinal swelling or increased thickness
– Secondly, these patients may have preexisting retinal thinning that creates a falsely normal OCT
Limitations
• Small number of Type 1 diabetics, results may not generalize
• Treated vs. untreated patients not controlled for and comparison between groups was not made
In Conclusion
• Fluorescein is still a useful clinical tool for assessment of leakage and guiding treatment
• Although OCT is a less invasive testing modality for detection of DME, up to 1/3rd of patients with active leakage will be missed
• OCT not surrogate for clinical exam or FA and cannot be used as a guide for placement of laser photocoagulation
Acknowledgements
• Rohan J. Shah, M.D.
• Franco Recchia, M.D.