Diabetic Retinopathy Clinical Trial
Official title:
The Course of Response to Focal Photocoagulation for Diabetic Macular Edema
The study objective is to determine the course of changes in OCT measured macular thickness
and visual acuity following a single session of focal photocoagulation for center-involved
DME. The response will be evaluated separately in eyes with and without prior focal
photocoagulation for DME. The purpose is to determine the proportion of eyes that continue
to improve at least 5 letters in visual acuity or at least 10% in central retinal thickness
after a session of focal photocoagulation. In addition, the study will explore whether any
baseline factors can be identified that are predictive of the response.
All subjects will have follow-up visits 8 weeks and 16 weeks post treatment. At the 16-week
visit, study eyes are evaluated for change in retinal thickness and visual acuity from
baseline.
- Treatment is to be deferred and follow up continued if visual acuity letter score has
improved by >5 or OCT central subfield thickness has decreased by >10% compared with
baseline.
- If visual acuity letter score has not improved by at least 5 and OCT central subfield
thickness has not decreased by at least 10%, then the eye is classified as 'not
improved' and the investigator may provide additional treatment. Follow up ends for
eyes that receive additional treatment at this visit. However, if the investigator and
participant elect to defer additional treatment (even if deferral criteria are not
met), then follow up will continue until the study eye receives additional treatment
for DME.
- Eyes continuing in follow up have visits every 8 weeks (+1week) as long as there has
been continued improvement in visual acuity (letter score improved >5 ) or retinal
thickness (central subfield thickness decreased by >10%) compared with the visit 16
weeks earlier. The longest follow-up time will be 48 weeks.
By providing information on the length of time during which clinically meaningful
improvement occurs following focal photocoagulation, clinicians will be better able to
determine when further photocoagulation or other treatments should be considered for
persistent DME. Depending on the results of this study, a future randomized clinical trial
will be considered comparing the more aggressive retreatment photocoagulation regimen
currently serving as the standard DRCR Network approach to focal photocoagulation for
macular edema with the less aggressive regimen evaluated in this protocol.
Focal photocoagulation is the only treatment that has been demonstrated to be beneficial for
diabetic macular edema. In the ETDRS, focal photocoagulation of eyes with macular edema
reduced the risk of moderate visual loss (decrease of 15 or more letters) by approximately
50% (from 24% to 12%, three years after initiation of treatment). For eyes with
center-involved DME and visual acuity worse than 20/40 that were treated with focal
photocoagulation, the 15-letter improvement rate at 1 year was 11% and at 3 years was 16%.
In the ETDRS, focal photocoagulation treatment for diabetic macular edema involved direct
treatment to discrete lesions between 500 microns and 3000 microns from the center of the
macula that were thought to be causing retinal thickening or hard exudates with or without
"grid" treatment to other macular areas of retinal thickening or non-perfusion. The lesions
treated directly included microaneurysms, identified on fluorescein angiography, that either
filled or leaked, intraretinal microvascular abnormalities (IRMA), or pruned capillaries
that leaked fluorescein. Grid treatment was applied in the ETDRS to areas of thickened
retina that showed diffuse fluorescein leakage or areas of non-perfusion identified as
capillary dropout on fluorescein angiography. Areas of non-perfusion in the macula could be
treated with grid at the discretion of the treating ophthalmologist. Areas that had both
discrete lesions and diffuse leakage or capillary dropout would receive a combination of
direct and grid treatment. Re-treatment was applied at four month intervals if clinically
significant macular edema persisted, one or more treatable lesions were identified, and the
investigator believed these lesions were responsible for the edema. The median number of
focal laser treatments applied in the ETDRS was 3.8.
The mechanism of action of focal photocoagulation is not fully understood; however, it is
clear that the retinal pigment epithelium (RPE) absorbs the majority of the laser energy and
thermal injury occurs at the level of the RPE. Studies have shown that photocoagulation can
eventually result in retinal and apparent RPE atrophy 200-300% larger than the original
laser spot size. These areas of expanded atrophy can lead to loss of central vision, central
scotomata, and decreased color vision. Consequently, many retinal specialists today tend to
treat with lighter, less intense laser burns than originally specified in the ETDRS.
In addition to the concern regarding the spread of intense laser burns, there are a number
of other reasons that retinal specialists today have modified the treatment procedures
originally specified in the ETDRS protocol. These reasons include the advent of new lasers
and the clinical observation that different techniques, such as focal photocoagulation with
lighter burns or grid treatment alone, may be similar in beneficial effect as the original
ETDRS treatment protocol. A modified ETDRS focal photocoagulation protocol adapted from the
original ETDRS approach, has been adopted as the standard laser technique for DME used in
DRCRnet studies.
There are limited data on the course of visual acuity and central retinal thickness after a
single focal photocoagulation session for DME. In prior DRCRnet DME treatment protocols that
included a laser arm, according to the re-treatment protocol eyes received a second focal
photocoagulation session at 3.5- 4 months (which was the first follow-up visit) unless there
was substantial improvement defined as at least a 50% decrease in retinal thickening of the
central subfield measurement on OCT. As a result, it is unknown what proportion of eyes with
lesser degrees of improvement would have continued to improve and the time course for
further improvement following the initial photocoagulation session given additional time. In
one study conducted by DRCRnet of eyes that had not been previously treated for DME, among
113 eyes in the modified ETDRS laser treatment group with baseline OCT central subfield >250
microns, a 50% or more reduction in OCT central subfield thickening was present at 3.5
months in only 28 (25%). The table below categorizes the 85 eyes that did not meet this
measure of improvement at 3.5 months with regard to improvement in visual acuity of at least
5 letters and/or reduction in central subfield thickness of at least 10%. The 5 letter
reduction was selected based on the 95% confidence interval for change determined in a study
that evaluated the validity and reliability of the electronic ETDRS visual acuity testing
procedure that is used in DRCRnet protocols. The 10% threshold was selected based on the
DRCRnet OCT reproducibility study which found that a 10% change in central subfield
thickness was likely to be real. Forty-seven (42%) eyes that met the protocol requirement
for repeat photocoagulation at the first follow-up visit had an improvement in either visual
acuity (of at least 5 letters), central subfield (of at least a 10% reduction), or both at
this follow-up visit.
Other DRCRnet protocols provide data on the course following a single photocoagulation
session through 4 months of follow up. In a pilot study designed to evaluate peribulbar
corticosteroids for mild DME (OCT central subfield thickness = 250 microns and visual acuity
20/40 or better at baseline), modified ETDRS focal photocoagulation was the treatment given
to the control group. Follow-up visits occurred after 1, 2, and 4 months before the eye was
eligible to be retreated. Twenty-one of the 37 eyes in the laser group had not been
previously treated with focal photocoagulation for DME and 17 eyes had been previously
treated with focal photocoagulation. A 50% or more reduction in OCT central subfield
thickening occurred in 11 (30%) of the 37 eyes at 17 weeks. Fourteen (38%) eyes that would
have met the criteria for re-treatment had an improvement in either visual acuity (of at
least 5 letters), central subfield (of at least 10%), or both at 17 weeks.
In another pilot study evaluating intravitreal bevacizumab for DME (OCT central subfield
thickness = 275 microns and visual acuity 20/32 or worse at baseline), modified ETDRS focal
photocoagulation was the treatment given to the control group. Follow-up visits occurred
after 3, 6, 9, and 12 weeks before the eye was eligible to be retreated. There were 7 eyes
in the laser group that had not been previously treated with focal photocoagulation for DME
and 12 eyes that had been previously treated with focal photocoagulation. Among these 19
eyes, a 50% or more reduction in OCT central subfield thickening occurred in 3 (16%) at 12
weeks. Ten (53%) eyes that would have met criteria for re-treatment had an improvement in
either visual acuity (of at least 5 letters), central subfield (of at least 10%), or both at
12 weeks.
The data from these three protocols indicate that a substantial number of eyes receiving
focal photocoagulation (either an initial course or repeat application) will show
improvement in central retinal thickness after 3-4 months that is at least 10% but is less
than 50% of the baseline thickening. It is for these eyes that further knowledge of the
course of retinal thickening and visual acuity without additional interventions is needed to
assess whether the present requirements for re-treatment are more aggressive than they need
to be.
;
Observational Model: Cohort, Time Perspective: Prospective
| Status | Clinical Trial | Phase | |
|---|---|---|---|
| Completed |
NCT03660371 -
ILM Peeling in PDR Patients Undergoing PPV for VH
|
N/A | |
| Completed |
NCT03660345 -
PPV With Internal Limiting Membrane Peeling for Treatment-Naïve DME
|
Phase 3 | |
| Completed |
NCT03660384 -
Silicone Oil Versus Gas in PDR Patients Undergoing Vitrectomy
|
N/A | |
| Completed |
NCT04905459 -
ARDA Software for the Detection of mtmDR
|
||
| Active, not recruiting |
NCT04271709 -
Manhattan Vision Screening and Follow-Up Study (NYC-SIGHT)
|
N/A | |
| Recruiting |
NCT03713268 -
Intraoperative OCT Guidance of Intraocular Surgery II
|
||
| Completed |
NCT05022615 -
Comparing 3 Imaging Systems
|
||
| Completed |
NCT00385333 -
Metabolic Mapping to Measure Retinal Metabolism
|
Phase 2 | |
| Recruiting |
NCT04101604 -
Biomarkers of Common Eye Diseases
|
||
| Completed |
NCT03702374 -
Combined Antioxidant Therapy on Oxidative Stress, Mitochondrial Dysfunction Markers in Diabetic Retinopathy
|
Phase 3 | |
| Completed |
NCT01908816 -
An Open-label Extended Clinical Protocol of Ranibizumab to Evaluate Safety and Efficacy in Rare VEGF Driven Ocular Diseases.
|
Phase 3 | |
| Completed |
NCT04009980 -
Long-term Retinal Changes After Topical Citicoline Administration in Patients With Mild Signs of Diabetic Retinopathy in Type 1 Diabetes Mellitus.
|
N/A | |
| Completed |
NCT02924311 -
Routine Clinical Practice for Use of Intravitreal Aflibercept Treatment in Patients With Diabetic Macular Edema
|
||
| Not yet recruiting |
NCT06257082 -
Video-based Patient Education Intervention for Diabetic Eye Screening in Latinx Communities
|
N/A | |
| Not yet recruiting |
NCT05452993 -
Screening for Diabetic Retinopathy in Pharmacies With Artificial Intelligence Enhanced Retinophotography
|
N/A | |
| Withdrawn |
NCT02812030 -
Aflibercept for Retinopathy in the Real World
|
N/A | |
| Completed |
NCT02391558 -
Clinical Evaluation of Noninvasive OCT Angiography Using a Zeiss OCT Prototype to Compare to Fluorescein Angiography
|
N/A | |
| Active, not recruiting |
NCT02353923 -
OcuStem Nutritional Supplement in Diabetic Patients With Mild to Moderate Non-proliferative Retinopathy
|
N/A | |
| Active, not recruiting |
NCT02330042 -
OCT Biomarkers for Diabetic Retinopathy
|
||
| Completed |
NCT02390245 -
Philadelphia Telemedicine Glaucoma Detection and Follow-Up Study
|
N/A |