Functional and Structural Imaging for Glaucoma
| Status: | Recruiting |
|---|---|
| Conditions: | Ocular |
| Therapuetic Areas: | Ophthalmology |
| Healthy: | No |
| Age Range: | 40 - 80 |
| Updated: | 4/17/2018 |
| Start Date: | September 2013 |
| End Date: | December 2022 |
| Contact: | Rachel McClain, COA |
| Email: | mcclainr@ohsu.edu |
| Phone: | 503-494-9628 |
Longitudinal Observational Study Using Functional and Structural Optical Coherence Tomography to Diagnose and Guide Treatment of Glaucoma
The specific aims of the clinical studies are to:
- Develop quantitative wide-field OCT angiography.
- Simulate visual field results by combining structural and angiography OCT data.
- Establish or validate age-adjusted normal reference ranges for above OCT-derived
parameters.
- Establish criteria for glaucoma diagnosis based on above imaging-derived parameters.
- Evaluate the sensitivity and specificity of above OCT-derived parameters
- Measure the rate of normal age-related change in above OCT-derived parameters.
- Assess the reproducibility of above OCT-derived parameters.
- Assess abilities of above OCT-derived parameters on predicting glaucoma conversion and
progression.
- Develop quantitative wide-field OCT angiography.
- Simulate visual field results by combining structural and angiography OCT data.
- Establish or validate age-adjusted normal reference ranges for above OCT-derived
parameters.
- Establish criteria for glaucoma diagnosis based on above imaging-derived parameters.
- Evaluate the sensitivity and specificity of above OCT-derived parameters
- Measure the rate of normal age-related change in above OCT-derived parameters.
- Assess the reproducibility of above OCT-derived parameters.
- Assess abilities of above OCT-derived parameters on predicting glaucoma conversion and
progression.
Glaucoma is the second leading cause of blindness in the US. The diagnosis and monitoring of
glaucoma are important problems, not only because of its prevalence, but also because of its
silent and irreversible nature. However all of the current diagnostic tests have serious
limitations. Although elevated intraocular pressure (IOP) is a risk factor, most glaucoma
patients actually have IOP within normal range. Visual field (VF) tests are poorly
reproducible, and a series of 3 tests are needed to establish diagnosis or confirm
progression. Although ophthalmoscopic examination can detect optic nerve head (ONH) and nerve
fiber layer (NFL) defects, reliability in diagnosis and tracking is hampered by its
subjective and semi-quantitative nature. Although quantitative imaging with optical coherence
tomography (OCT), scanning laser polarimetry (SLP), and confocal scanning laser
ophthalmoscopy (cSLO) can more objectively detect ONH and NFL defects, their diagnostic
accuracies are still not sufficient to be relied on alone for diagnostic screening. It has
been estimated that about half of glaucoma patients in the US do not know that they have the
disease. Thus, there is a need for improvements in glaucoma diagnostic technologies. One
approach that deserves further exploration is blood flow imaging.
There is much circumstantial evidence that vascular factors play important roles in the
pathophysiology of glaucoma:
1. Systemic vasculopathy increases the risk of developing glaucoma. Hypertension, diabetes,
and vasospastic conditions are all known risk factors. Normal tension glaucoma has also
been linked to peripheral endothelial dysfunction and erectile dysfunction. This
suggests that poor circulation may be a causative factor or a facilitative factor that
predisposes the ONH to damage by elevated IOP.
2. Decrease or fluctuation in ocular perfusion pressure was identified as an independent
risk factor for progression in the Collaborative Normal-Tension Glaucoma Study and other
studies. Nocturnal hypotension is also a risk factor for glaucoma progression.
3. Medications that improve ocular perfusion appear to have protective effects that are not
explained by the lowering of IOP.
4. Optic disc hemorrhage and peripapillary atrophy are both associated with accelerated
glaucoma progression. These finding may support a role for focal ischemia.
5. Animal experiments show that increased IOP causes decreased ONH blood flow in the
presence of low systemic blood pressure.
Despite the evidence, the management of glaucoma remains focused on the lowering of IOP, the
one causative factor that responds to treatment and can be easily measured. Blood flow
measurement is a research topic, but currently has no clinical role in the diagnosis,
prognostic evaluation, or treatment of glaucoma. Therapies aimed at improving ocular
circulation cannot be effectively developed without a practical method for quantitative and
reproducible evaluation of ONH and retinal perfusion. Thus there is a great need to develop
better technology for the evaluation of ocular circulation.
Using high-speed OCT systems, we have developed new methods to image and measure optic nerve
head (ONH) and retinal blood flow. Preliminary results showed that VF loss was more highly
correlated with retinal blood flow as measured by OCT than any neural structure measured by
OCT or other imaging modality. Accordingly, the goal of the proposed project is to improve
the diagnostic and prognostic evaluation of glaucoma by further developing novel functional
OCT measurements using ultrahigh-speed (70-100 kHz) OCT technology.
Retinal blood flow, ONH circulation, optic disc rim volume, peripapillary nerve fiber layer
volume, and macular ganglion cell complex volume are all pieces of the same glaucoma puzzle.
This project will develop novel imaging methods that allow us to look at the whole picture
using one tool - ultrahigh-speed OCT.
glaucoma are important problems, not only because of its prevalence, but also because of its
silent and irreversible nature. However all of the current diagnostic tests have serious
limitations. Although elevated intraocular pressure (IOP) is a risk factor, most glaucoma
patients actually have IOP within normal range. Visual field (VF) tests are poorly
reproducible, and a series of 3 tests are needed to establish diagnosis or confirm
progression. Although ophthalmoscopic examination can detect optic nerve head (ONH) and nerve
fiber layer (NFL) defects, reliability in diagnosis and tracking is hampered by its
subjective and semi-quantitative nature. Although quantitative imaging with optical coherence
tomography (OCT), scanning laser polarimetry (SLP), and confocal scanning laser
ophthalmoscopy (cSLO) can more objectively detect ONH and NFL defects, their diagnostic
accuracies are still not sufficient to be relied on alone for diagnostic screening. It has
been estimated that about half of glaucoma patients in the US do not know that they have the
disease. Thus, there is a need for improvements in glaucoma diagnostic technologies. One
approach that deserves further exploration is blood flow imaging.
There is much circumstantial evidence that vascular factors play important roles in the
pathophysiology of glaucoma:
1. Systemic vasculopathy increases the risk of developing glaucoma. Hypertension, diabetes,
and vasospastic conditions are all known risk factors. Normal tension glaucoma has also
been linked to peripheral endothelial dysfunction and erectile dysfunction. This
suggests that poor circulation may be a causative factor or a facilitative factor that
predisposes the ONH to damage by elevated IOP.
2. Decrease or fluctuation in ocular perfusion pressure was identified as an independent
risk factor for progression in the Collaborative Normal-Tension Glaucoma Study and other
studies. Nocturnal hypotension is also a risk factor for glaucoma progression.
3. Medications that improve ocular perfusion appear to have protective effects that are not
explained by the lowering of IOP.
4. Optic disc hemorrhage and peripapillary atrophy are both associated with accelerated
glaucoma progression. These finding may support a role for focal ischemia.
5. Animal experiments show that increased IOP causes decreased ONH blood flow in the
presence of low systemic blood pressure.
Despite the evidence, the management of glaucoma remains focused on the lowering of IOP, the
one causative factor that responds to treatment and can be easily measured. Blood flow
measurement is a research topic, but currently has no clinical role in the diagnosis,
prognostic evaluation, or treatment of glaucoma. Therapies aimed at improving ocular
circulation cannot be effectively developed without a practical method for quantitative and
reproducible evaluation of ONH and retinal perfusion. Thus there is a great need to develop
better technology for the evaluation of ocular circulation.
Using high-speed OCT systems, we have developed new methods to image and measure optic nerve
head (ONH) and retinal blood flow. Preliminary results showed that VF loss was more highly
correlated with retinal blood flow as measured by OCT than any neural structure measured by
OCT or other imaging modality. Accordingly, the goal of the proposed project is to improve
the diagnostic and prognostic evaluation of glaucoma by further developing novel functional
OCT measurements using ultrahigh-speed (70-100 kHz) OCT technology.
Retinal blood flow, ONH circulation, optic disc rim volume, peripapillary nerve fiber layer
volume, and macular ganglion cell complex volume are all pieces of the same glaucoma puzzle.
This project will develop novel imaging methods that allow us to look at the whole picture
using one tool - ultrahigh-speed OCT.
Inclusion Criteria: Normal Subjects (both eyes must meet all criteria)
1. No history or evidence of retinal pathology or glaucoma
2. Normal Humphrey 24-2 VF: A mean defect (MD), corrected pattern standard deviation
(CPSD) within 95% limits of normal reference, and glaucoma hemifield test (GHT) within
normal limits (97%).
3. Intraocular pressure < 21 mm Hg
4. Central corneal pachymetry > 500 microns
5. No chronic ocular or systemic corticosteroid use
6. Open angle (gonioscopy must show 75% or more of the angle to be Grade 2 or more by
Shaffer's grading system)
7. Normal appearing ONH and NFL: vertical and horizontal cup/disc ratio (CDR) ≤ 0.5 and
intact neuroretinal rim without peripapillary hemorrhages, notches, localized pallor,
or NFL defect
8. Symmetric ONH between left and right eyes: CDR difference < 0.2 in both vertical and
horizontal dimensions
Inclusion criteria: Glaucoma Group
1. ONH or NFL defect visible on slit-lamp biomicroscopy defined as one of following:
1. diffuse or localized thinning of the rim
2. disc (splinter) hemorrhage
3. notch in the rim
4. vertical cup/disc ratio greater than the fellow eye by > 0.2
2. Presence or absence of VF defects as measured by Humphrey SITA 24-2 VF.
Exclusion Criteria: All Groups
1. Best-corrected visual acuity less than 20/40
2. Age < 40 or >80 years
3. Refractive error of > +3.00 D or < -7.00 D
4. Previous intraocular surgery except for uncomplicated cataract extraction with
posterior chamber intraocular lens implantation
5. Diabetic retinopathy
6. Other diseases that may cause VF loss or optic disc abnormalities
7. Inability to clinically view or photograph the optic discs due to media opacity or
poorly dilating pupil
8. Inability to perform reliably on automated VF testing
9. Life-threatening or debilitating illness making it unlikely patient could successfully
complete the study.
10. Refusal of informed consent or of commitment to the full length of the study
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