Advanced Primary Care Optometry (10328) Lecture Notes PDF

Summary

These lecture notes detail OCT imaging principles. They cover A-scans, B-scans, volume scans, and associated technologies. The document also discusses learning objectives, prescribed reading for the subject, and includes a pop quiz preview.

Full Transcript

Advanced Primary Care Optometry (10328)

Optical coherence tomography of
the posterior eye

Dr Agnes Choi and
Dr Vicki Evans
 Acknowledgement of Country

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contribution they make to the life of Canberra and the region.

We also acknowledge all other First Nations Peoples on whose land
we gather.
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Prescribed Reading
Ly A et al. An evidence-based approach to the
routine use of optical coherence tomography.
Clin Exp Optom 2019; 102:242-259
 Pop Quiz preview
Explain the optical principles of OCT imaging
What is the difference between and A-scan, B-scan and volume scan?
What are the key retinal segmentations applied in OCT?
What are the main types of scan you can use with an OCT and why would you use
each one?
What is red disease and green disease?
What are the post-hoc analysis indices commonly used in OCT and how are they
applied?
Compare and contrast the report format of three main types of OCT images
If using GPA, what are you measuring?
Identify and describe how to correct common artifacts in OCT imaging
Describe OCT-A and a clinical indication for OCT-A
 Learning Objectives
What is optical coherence tomography
How to do it
When to use it
Watch out for artifacts
OCT-Angiography in a nutshell
 What is it
Technology basics
 OCT has much higher resolution than ultrasound, MRI, CT or cSLO
Comparison of resolution in axial and
lateral direction between some medical
imaging techniques for different body
parts.
Skin/cornea: reflectance confocal
microscopy (RCM).
Retina: confocal scanning laser
ophthalmoscopy (cSLO), adaptive optics
scanning laser ophthalmoscopy (AOSLO) ,
optical coherence tomography (OCT),
adaptive optics optical coherence
tomography (AO-OCT).
General: magnetic resonance imaging
(MRI), computed tomography (CT),
medical ultrasound

Aumann, S., Donner, S., Fischer, J., Müller, F. (2019). Optical Coherence Tomography (OCT): Principle and Technical Realization. In: Bille, J. (eds) High Resolution
Imaging in Microscopy and Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
Cross sectional view.

A beam of light typically
800-1400 nm near infrared
is scanned across the tissue
sample.

Measured time of flight
delay.

Superficial layer has
shorter propagation delay
than deeper layers.

Costa et al 2006 Prog Retin Eye Res
 A-scans
Amplitude can be plotted
against the time of flight delay
in the axial plane.
This reveals changes in
amplitude of tissue reflectivity
over the depth of the retinal.
Amplitude of reflection or
A-scan (similar to ultrasound).

Costa et al 2006 Prog Retin Eye Res
 B-scans
Many A-scans (red lines)
are combined to provide a
B-scan cross sectional
image through one line

Costa et al 2006 Prog Retin Eye Res
Costa et al 2006 Prog Retin Eye Res
 Volume scans
Many B-scans are combined to
provide a volume scan.
This creates a cube of information
and the surface of the cube is called
the enface plane.
This allows calculation of thickness
over an area or region.

Aumann S., Donner S., Fischer J., Müller F. (2019) Optical Coherence Tomography (OCT): Principle and Technical Realization. In: Bille J. (eds)
High Resolution Imaging in Microscopy and Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
 Basic principles of Interferometry
Non-invasive technique for examining ocular structure by cross
sectional imaging.
Allows real-time viewing of tissues.
Interferometry techniques used a photo-detector to collect back-
scattered light from a scanning near infrared source.
Source light is split into two separate paths by the interferometer
then re-combines the light coming back from the two paths at the
interferometer output
This reflected light is measure by the detector
Time and amplitude variation is generated between structures of
different depth and reflectivity.
Aumann, S., Donner, S., Fischer, J., Müller, F. (2019). Optical Coherence Tomography (OCT): Principle and Technical Realization. In: Bille, J. (eds) High Resolution
Imaging in Microscopy and Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
Super luminescent
diode Interferometer
Coupler measures the effect
of combining two
light waves.
If the wavelengths are coherent (can be
Converted to
electrical current superimposed, or are in-phase) as they
travel over time, they can add
constructively (i.e. they amplify each other)
or destructively (i.e. they cancel out each
other) or anything in between

Costa et al 2006 Prog Retin Eye Res Aumann, S., Donner, S., Fischer, J., Müller, F. (2019).
 Temporal Domain OCT
Light from the light source is split into the reference
beam and the central beam.

To record one depth profile of the sample (amplitude
scan or A-scan) the reference arm needs to be
scanned. This has to be repeated for each lateral scan
position.

Back reflected light from both arms is combined again
at the fibre optic coupler and recorded by the detector.

The signal processor transforms the waves into peaks
of amplitude (A-scan)

To create a cross-sectional image (or B-Scan), the
sample beam is scanned laterally across the sample.
This abbreviation originated in ultrasound imaging,
where B-Scan means brightness scan.
Aumann, S., Donner, S., Fischer, J., Müller, F. (2019). Optical Coherence Tomography (OCT):
Principle and Technical Realization. In: Bille, J. (eds) High Resolution Imaging in Microscopy and
Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
 Comparison of technologies
Time Domain Fourier Domain
low coherent light source 2nd generation of OCT technology
acquisition of a depth scan for every location to generate an more efficient implementation of the principle of low-
A-scan coherence interferometry
lateral scans required to generate B-scan uses spectral information to generate A-scans without the
very slow imaging speed and poor image quality need for mechanical scanning of the optical path length
noisy images impede use for clinical diagnosis

Spectral Domain Swept Source Domain
3rd generation, broad wavelength spectrum light source 4th generation, the optical source rapidly sweeps a narrow
captures whole depth information simultaneously line-width over a broad range of wavelengths
improved image speed and quality, determined by linescan one wavelength sweep constitutes a spectral interferogram
rate of camera with fringe patterns, as in SD-OCT
co-localisation of fundus scan with cross-sectional OCT the interferogram contains information for all depth layers of
images improves motion tracking the sample simultaneously
improved usefulness for diagnosis acquisition speed is given by the sweep rate of the swept-
source and subsequent AD
Aumann, S., Donner, S., Fischer, J., Müller, F. (2019). Optical Coherence Tomography (OCT): Principle
and Technical Realization. In: Bille, J. (eds) High Resolution Imaging in Microscopy and
Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
 Optical setup of spectrometer
based OCT (SD-OCT) and swept
source OCT (SS-OCT).

While SD-OCT uses a spectrometer for
wavelength separation, SS-OCT features
a light source which sweeps the
wavelength in time.

Both implementations record an
interference spectrum which carries the
depth in formation of the sample.
FFT is used to transform the interference
signal into the A-scan.

Aumann, S., Donner, S., Fischer, J., Müller, F. (2019). Optical Coherence Tomography (OCT): Principle and Technical Realization. In: Bille, J. (eds) High Resolution
Imaging in Microscopy and Ophthalmology. Springer, Cham. https://doi.org/10.1007/978-3-030-16638-0_3
There are an
ever-growing
number of OCT
instruments on
the market

OPTOMETRY
AUSTRALIA
OCT BUYER’S
GUIDE 2018

https://www.o
ptometry.org.a
u/wp-
content/uploa
ds/Publications
/Equipment/E
Q-OCT-buyers-
guide-2018.pdf
 Spectralis Heidelberg Cirrus Zeiss RS Duo 2 Nidek Maestro 2 Topcon
Spectral Domain Spectral Domain Spectral Domain Spectral Domain
40-80k A-scan/sec 27-68 A-scan/sec 53k A-scan/sec 50k A-scan/sec

https://www.nidek-
How to acquire the perfect image, https://www.beye.com/product/cirrus-hd- intl.com/product/ophthaloptom/diag https://topconhealthcare.com/products/
HRA+OCT Spectralis, Heidelberg oct-500 nostic/dia_retina/duo2.html maestro2/
Engineering Academy
 Line scan of
macula

Retina and Glaucoma Imaging Platform Spectralis
RPE
Bruchs membrane
Choroid
 Line scan of
macula

Staurenghi et al 2014 Ophthalmol
 Segmentation
https://iacl.ece.jhu.edu/index.php/Retinal_layer_segmentation_of_macular_OCT_images

Figure 1: (a) A typical retinal OCT image (B-scan) enlarged with the layers labeled on the right-hand side. Every B-scan
consists of a set of vertical scan lines (A-scans). The fovea is characterized by a depression in the surface of the retina
where the top five (inner) layers are absent. (b) A fundus image with lines overlaid representing the locations of every B-
scan within a volume. The red line corresponds to the B-scan in (a).
 Structure and depth
Most OCTs allow simultaneous viewing of fundus (IR) with OCT scan, many now incorporate
cSLO colour imaging of the fundus as well.
This is incredibly useful for tracking change in clinical pathologies such as neovascular AMD
and glaucoma

file:///C:/Users/s437761/Downloads/303057-002_SPECTRALIS_Sales%20Tool_cSLO%20Retinal%20Modalities%20Sheet_US.pdf
How to do it
The main things
 OCT scan pattern and examples of use
You can shoose:
Line
– Macula
– Optic nerve head
Volume
– Macular thickness
– Ganglion cell layer thickness
Circle
– TSNIT graph

Panda et al 2018 Comput Med Imaging Graph
Line scan
 Line scan of
macula

Staurenghi et al 2014 Ophthalmol
Minimum distance between ILM and
Bruch’s membrane opening around
Line scan of an optic nerve
the optic nerve head (BMO-MRW) head, disc margin

Staurenghi et al 2014 Ophthalmol
Glaucoma Module Premium Edition Spectralis
Volume scan
 Spectralis OCT
macular scan

https://www.opticianonline.net/cet-archive/123
 Cirrus OCT
macular scan –
macular
thickness
analysis

Cirrus HD-OCT User Manual - Models 500, 5000
 Cirrus OCT
macular scan –
ganglion cell
layer thickness
analysis

Bounded by
purple and
yellow line
GCL + IPL
thickness
 Nidek OCT
macular scan

Ganglion cell complex
(GCC) = RNFL + GCL + IPL

Bruce 2014 Pharma March Optometry Australia
Circle scan
 Cirrus OCT
RNFL scan

https://www.ophthalmologymanagement.com/issues/2011/july-2011/the-expanding-role-of-sdoct-in-practice
Spectralis OCT
RNFL scan

Check size of circle
Check segmentation is correct

Glaucoma Module Premium Edition Spectralis
 Nidek OCT
RNFL scan

Disc margin is
shortest distance
from BMO to ILM

https://nidek-oct.com/glaucoma-diagnostics
Putting it all together
 Cirrus report

Neuroretinal rim thicknesses, defined as the
distance between the optic disc margin and
cup margin at a specific point, in a 360°
circumferential area are presented as a
neuroretinal rim thickness curve with Cirrus
HD-OCT. (TSNIT graph.)

https://www.zeiss.co.uk/content/dam/Meditec/gb/Chris/OCT%20Busin
ess%20Builder/PDF%27s/1.pdf
 Spectralis report

Arthur, S., Smith, S., Wright, M. et al. Reproducibility and agreement in evaluating
retinal nerve fibre layer thickness between Stratus and Spectralis OCT. Eye 25, 192–
200 (2011). https://doi.org/10.1038/eye.2010.178
Maestro report

https://lombartinstrum
ent.com/products/topc
on-3d-oct-1-maestro2-
spectral-domain-oct/
Topcon Maestro 2 https://www.reviewofoptometry.com/article/how-do-oct-devices-for-glaucoma-compare
Glaucoma progression analysis Deviation maps
When to use it
Clinical applications
Clinical Application 1
Glaucoma
 46 y.o. Caucasian female
6/6 each eye
IOP 15 mmHg each eye
Gonioscopy showed open angles
Pachymetry was 579 μm each eye
Large cups OU (OD > OS)
HFA VF showed no glaucomatous field
defects each eye
RNFL within normal limits each eye –
circle scan
Macular retinal thickness map showed
an arc of thinning extending infero-
temporally from the optic disc OD –
volume scan Spectralis
Asymmetry analysis showed the
arcuate defect on the right-left
comparison and the superior-inferior
comparison. Asrani et al 2011 Arch Ophthalmol
 56 y.o. Caucasian female
OD 6/6 OS 6/9
IOP OD 19 mmHg OS 21 mmHg
Sloped inferior rim OD and thin inferior
rim OS
HFA VF:
a superior nasal step and a small
superior paracentral defect OD
a superior hemifield defect and an
early inferior paracentral defect OS
RNFL:
inferotemporal thinning OD
Inferior and temporal thinning OS
Macular retinal thickness map:
inferior defect OD highlighted in
superior-inferior comparison
inferior defect highlighted in
superior-inferior comparison
overall thinner retinal thickness OS
highlighted in right-left comparison
Asrani et al 2011 Arch Ophthalmol
Cryer 2016 Pharma June Optometry Australia
 Clinical Application 2
Optic neuropathy and papilloedema
 http://webeye.ophth.uiowa.edu/eyeforum/c
ases/72-optic-nerve-drusen-visual-field-
loss.htm

https://www.ophthalmologymanagement.com/issues/2011/july-2011/the-expanding-role-of-
sdoct-in-practice
https://www.ophthalmologymanagement.com/issues/2011/july-2011/the-expanding-role-of-sdoct-in-practice
 Healthy

Mild papilloedema

Severe papilloedema

Vartin et al 2012 Br J Ophthalmol
Clearly visible ODD A few visible ODD Buried ODD
Hamann et al 2018 Acta Ophthalmol
 Clinical Application 3
Age-related macular degeneration
https://www.opticianonline.net/features/macular-degeneration-case-study
 Clinical Application 4
Central Serous Chorioretinopathy
Pole et al 2020 Am J Ophthalmol Case Rep
 Clinical Application 5
Diabetic retinopathy and macular
oedema
Before focal/grid laser 6 months after laser

DM
macular oedema

Hirano et al 2014 Ophthalmic Res
Chauhan 2015 Pharma September Optometry Australia
OCT Artifacts
 Operator-
dependent artifact
– Truncation

Incorrect thickness
measurement

Asrani et al 2014 JAMA Ophthalmol
 Ocular cause
of artifact –
epiretinal
membrane

Incorrect
segmentation

Asrani et al 2014 JAMA Ophthalmol
 Ocular cause of
artifact – posterior
vitreous
detachment

Erroneous
elevation in RNFL
thickness because
traction released

Asrani et al 2014 JAMA Ophthalmol
 Machine error

Incorrect
segmentation

https://www.reviewofophthalmology.com/article/dont-be-fooled-spotting-oct-artifacts
 Motion
artifact

Incorrect
segmentation

Incomplete
segmentation
https://www.reviewofophthalmology.com/article/dont-be-fooled-spotting-oct-artifacts
 Floater

Ocular cause of
artifact – Floater

Missing data

Liu et al 2015 Am J Ophthalmol
OCT-Angiography
 Basic principle of OCT-A

Uses the principle of “motion contrast” to
detect blood flow
Differing patterns of reflectance across time
due to red blood cell movement within tissue.
To detect motion, we must image the exact
same retinal location four consecutive times.
Majcher and Johnson Review of Optometry March 15, 2017. https://www.reviewofoptometry.com/article/imaging-motion-a-review-of-
octa#:~:text=OCT%2DA%20imaging%20is%20based,blood%20cell%20movement%20within%20tissue.&text=To%20detect%20motion%2C%20we%20must,acquiring%20four%20macular%20cube%20scan
s).
 Basic principle
of OCT-A

Uses the
principle of
“motion
contrast” to
detect blood
flow

https://www.nidek-intl.com/archives/004/201902/5c763ea7a8890.pdf
Majcher and Johnson Review of Optometry March 15,
2017.
https://www.reviewofoptometry.com/article/imaging-
motion-a-review-of-
octa#:~:text=OCT%2DA%20imaging%20is%20based,blood
%20cell%20movement%20within%20tissue.&text=To%20
detect%20motion%2C%20we%20must,acquiring%20four
%20macular%20cube%20scans).
Pole et al 2020 Am J Ophthalmol Case Rep
Superficial capillary Deep capillary plexus Outer retina Choroid
plexus (SCP) (DCP)
https://www.nidek-intl.com/archives/004/201902/5c763ea7a8890.pdf
Now it’s your turn!
What can you see?
Which scan will you use?
 Inf temp thinning, wedge
defect
RNFL scan (circle) TSNIT
graph
Posterior pole asymmetry
analysis (volume)
Ganglion cell layer analysis
(Cirrus, Nidek)

Panda et al 2018 Comput Med Imaging Graph Asrani et al 2011 Arch Ophthalmol
 OS Silver wiring, microvascular
changes, beading
Volume scan infero-nasal
to the optic disc, px look a
little to RHS

Searching for Clues on OCT images, Spectralis Basics of OCT
interpretation, Heidelberg Engineering Academy
Ahmad and Carrim 2017 Optom Vis Sci
 Retinal haemorrhage &
OD drusen neovasc AMD
Volume scan
Px looks a little to RHS

Ong and Guymer 2016 Pharma June Optometry Searching for Clues on OCT images, Spectralis Basics of OCT
Australia interpretation, Heidelberg Engineering Academy
Prescribed Reading
Ly A et al. An evidence-based approach to the
routine use of optical coherence tomography.
Clin Exp Optom 2019; 102:242-259
 Pop Quiz your turn
Explain the optical principles of OCT imaging
What is the difference between and A-scan, B-scan and volume scan?
What are the key retinal segmentations applied in OCT?
What are the main types of scan you can use with an OCT and why would you use
each one?
What is red disease and green disease?
What are the post-hoc analysis indices commonly used in OCT and how are they
applied?
Compare and contrast the report format of three main types of OCT images
If using GPA, what are you measuring?
Identify and describe how to correct common artifacts in OCT imaging
Describe OCT-A and a clinical indication for OCT-A
Thank you!