Transcript Slide 1
Enhanced sensitivity to detect very early
abnormalities in very asymmetric
Keratoconus
e-Poster
P186
Marcella Q. Salomão, MD;
Renato Ambrósio Jr., MD, PhD;
Leonardo N. Pimentel; Isaac Ramos;
Bruno Valbon; Ana Laura C. Canedo.
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Dr. Ambrósio is consultant for Oculus Optikgeräte GmbH (Wetzlar, Germany)
Introduction
Keratoconus (KC) is a non-inflammatory, usually bilateral, progressive
corneal degeneration, in which the corneal shape distorts, with progressive
stromal thinning and ectasia.
e-Poster
P186
A small percentage of cases present with a very asymmetric pattern. In
some cases, the asymmetry can be so significant that the contra-lateral eye
presents with normal anterior curvature (axial) maps.
A bilateral presentation as in these “normal” eyes may occur and could
even be the explanation for many cases of ectasia after LASIK with no
identifiable pre-operative risk factors.
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Identifying asymptomatic cases with normal slit lamp exam, good
spectacle corrected visual acuity, and normal corneal topography is critical;
not only for screening of refractive surgery candidates, but to allow an
enhanced treatment choice.
Purpose
To investigate the efficacy of combined tomographic and biomechanical indices
to detect very mild ectatic abnormalities or ectasia susceptibility in cases with
proven form fruste keratoconus.
Methods
e-Poster
P186
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Retrospective study
23 “topographically normal”
eyes with no diagnosis of
keratoconus (KC) or keratoconus
suspect (KCS) by the Nidek
Corneal Navigator System using
the Magellan Placido’s Corneal
Topographer, from 23 patients
who had clinical diagnosis of
keratoconus only in the fellow
eye.
Red= KC Eye
Green = Fellow Eye“topographically normal” (Forme FrusteKC)
*BuscemiPM. Nidek corneal navigator software for topographic analysis of corneal states. J
Refract Surg. 2004;20(5 Suppl):S747-50.
Placido’sTopography -both eyes of 23 very asymmetric Keratoconus
(Axial Maps, Smolek-Klyce Absolute Scale)
e-Poster
P186
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Belin/Ambrósio Enhanced Ectasia Display (BAD)
Belin’s Enhanced Reference Surface
e-Poster
P186
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Elevation maps considering the standard BFS were
subtracted from the elevation maps with the
enhanced BFS; and the highest difference between
the maps in the central 4mm area was noted for
anterior and posterior corneal surfaces.
The differential map contains only 3 colors, each one
corresponding to the amount of elevation change
that occurs when moving between the standard and
enhanced maps.
Anterior - green is anything < 6, yellow is between 6 12, red is > 12
Posterior: green is anything < 8, yellow is between 8 20, red is > 20
Yellow and red maps were considered abnormal.
Belin/Ambrósio Enhanced Ectasia Display (BAD)
Clinical example
Maguellan OD
Maguellan OS
Pentacam OD
Pentacam OS
e-Poster
P186
BAD OD
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Belin/Ambrósio Enhanced Ectasia Display (BAD)
Ambrosio’s Pachymetric Distribution
The Corneal Thickness Spatial Profile (CTSP) represents the averages of
thickness values of the points on 22 imaginary circles centered on the
thinnest point with increased diameters at 0.4 mm steps. The Percentage of
increase in thickness (PTI) starting from the thinnest point is also
calculated.
e-Poster
P186
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
The calculated values are displayed in a progression graph,
starting on the thinnest point, as the CTSP and PTI lines. Data
from a 95% confidence interval of a normal population is also
displayed, so that the clinician can compare the profile of each
eye to a normal population.
Abnormally thin corneas (ectatic) usually show abrupt and
abnormal profiles, out of the 95% CI.
Pachymetric Progression Index (PPI) for Minimal, Maximal and Average of
all hemi-meridians were noted.
Ambrósio’s Relational Thickness (ART) is the thinnest point (TP) divided
by PPI (Ave, Max).
Belin-Ambrósio deviation (BAD) combined index (D) from the deviation of normality of the front
(dF) and back (dB) enhanced elevation, pachymetric progression (dP), thinnest value (dT) and vertical
displacement (dY) were obtained from Pentacam.
Corneal Biomechanics with ORA (Ocular Response Analyzer)
Corneal response to a collimetric air pulse is monitored
by the infrared light reflection (applanation => peak)
It detects two applanation events correlated with the
air pulse pressure (INWARD- p1 and OUTWARD- p2)
e-Poster
P186
The delay of p2 is caused by corneal viscous damping
[CH = p1 – p2] and [CRF = p1 - (K * p2)]
Normal Values: CH: 10.17 ± 1.82 (range 3.23 to 14.58)
CRF: 10.14 ± 1.8 (range 5.45 to 15.1)
Ectasia leads to lower CH and CRF and altered signals
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
CH or CRF < 8.8mmHg is considered a relative contra Normal
indication for LASIK based on normal population values n=174
KC
n=23
Advanced ORA signal analysis are under study
CH
CRF
10.17
10.14
± 1.82
± 1.8
9,84
8,83
± 1.93
± 2.13
Results
All cases were detected by at least two parameters.
All
parameters (5Ds) were significantly different in the FFKC as compared
to the Normal group (Mann–Whitney–Wilcoxon test, p<0.05).
Area
under the ROC curve (AUROC) for the final Belin/Ambrósio
deviation index (D) was 0.976
e-Poster
P186
100
80
BAD D:
BAD Db:
BAD Dy:
BAD Df:
BAD Dp:
BAD Dt:
Sensitivity
60
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
40
20
0
0
20
40
60
100-Specificity
80
100
n=23
n=23
n=174
Results
Areas
under the ROC curves (AUROC) for ART-Ave and ARTMax were 0.942 and 0.957
Best cut-off values were 1.27 (D), 512 (ART-Ave) and 391 (ARTMax)
100
Sensitivity
e-Poster
80
ART Avg.:
ART Max.:
Ele B BFS 8mm Thinnest:
Ele B BFTE 8mm Thinnest:
Pachy Min.:
RPI Max.:
60
40
20
n=23
0
0
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
20
40
60
100-Specificity
80
100
ART-Max
had the highest sensitivity for detecting ectasia susceptibility
(21 from 23 cases [91%] were lower than 400 microns)
The
2 cases with ART-Max of 440 and 481 had CH and/or CRF lower
than 8.8mmHg and low peaks on the ORA waveform.
Conclusions
e-Poster
P186
Rio de Janeiro
Corneal
Tomography
and
Biomechanics
Study Group
Identification of ectatic corneas is critical because this is the most important risk
factor for Iatrogenic keratectasia (along with CCT, ablation depth, age, residual
stromal bed and multiple treatments).
Placido’s Topography (surface curvature map) enables the detection of sub-clinical
(forme fruste) KC and PMD in eyes with normal slit lamp exam and good BSCVA,
but…
There are cases with ectatic progression with normal topography and no other risk
factors; and such cases illustrate the NEED for improving of identifying corneas at
risk for ectasia (ECTASIA SUSCEPTIBILITY).
Corneal Ectasia is a bilateral disease, characterized by progressive corneal thinning
and protrusion, due to an abnormal corneal structure. Thereby, corneal ToMography
(CTm) and biomechanical tests are likely more sensitive and specific.
3D Corneal ToMography provides further details beyond the surface, and CTmderived parameters allows for the diagnosis of very mild forms of ectasia and its
predisposition.
Enhanced ectasia screening successfully identified very mild forms of ectasia
undetected by a Placido-based neural network artificial intelligence system based on
front curvature data. Therefore, these new parameters increased sensitivity and
specificity for the screening process and should be part of the refractive surgery
candidates screening.