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What is OCT?

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Title: What is OCT?


1
Volumetric multiple wavelength ultrahigh
resolution imaging in glaucomatous retina Marilyn
Puah
Biomedical Imaging Group, School of Optometry and
Vision Sciences
  • Eye
  • Retina of eye consists of 10 layers
  • Nerve fibres in the eye exit via the optic nerve
    head to the brain
  • A flat disc or disc or shallow depth is
    indication of a healthy optic nerve head
  • Principle of OCT
  • Measures time delay and magnitude of optical
    echoes at different transverse positions
  • Dimensions of structures at different depths are
    based on echo time for light to be
    backscattered
  • By scanning optical beam in the transverse
    direction and performing successive axial scan
    measurements, cross sectional image is produced
  • A 2D grey scale or false colour image is produced
  • What is OCT?
  • Ultrahigh resolution optical coherence tomography
    (UHR OCT) is an upcoming new technology that
    allows non-invasive, optical medical diagnostic
    imaging.
  • Analogue to ultrasound but it allows real-time in
    situ imaging with higher resolution of 1 to 15
    microns.
  • It enables a three-dimensional in vivo direct
    visualization of the microstructure of the
    retina, allowing both qualitative and
    quantitative changes to be seen which are
    beneficial in diagnosing optical diseases
    especially in early stages.
  • OCT measures by echo time delay and intensity of
    back reflected light

Figure 5. Cross section of the eye, optic nerve
head and retina
  • What is glaucoma?
  • Glaucoma is one common disease of the eye in
    human
  • Characterized by increase in intraocular pressure
    and atrophy in the optic nerve head with
    corresponding visual field loss which is usually
    not noticeable by patient until a late stage
  • Optic atrophy results in a larger cup disc size
    and depth, which is seen as a dip from the cross
    section of the optic nerve head.
  • Several studies done have proposed that
    structural changes of the optic nerve head and
    nerve fibre layer will precede before visual
    field loss appear.
  • Therefore it is crucial to detect it early so
    that appropriate treatment can be done to prevent
    further damage to the optic nerves.

Figure 2. How OCT generates images
  • Methods
  • In vitro measurements of glaucomatous animal
    retinas were taken with microscope OCT
  • Allows three-dimensional imaging and
    visualisation of the morphological changes of the
    optic nerve head
  • Images intraretinal contrast were then compared
    to histology
  • Allows the improvement of OCT system in regards
    to resolution, contrast and penetration depth for
    future studies
  • 3 pairs of tree shrews eyes and 5 pairs of
    rats eyes were imaged
  • Glaucoma introduced in the left eye and right eye
    as a control
  • All retinas were processed using ImageJ
  • Best 3 pairs of eyes were chosen for this
    presentation
  • Comparison with other imaging techniques
  • Ultrasound allows increased penetration depth for
    imaging with higher frequency sound waves
  • But resolution is reduced due to increased
    ultrasonic attenuation
  • Confocal microscopy allows submicron resolution
  • But image penetration is limited
  • OCT strikes a balance between confocal microscopy
    and ultrasound imaging
  • OCT allows image penetration up to 2-3mm and
    resolution ranging from 15 to 1µm which is
    dependent on bandwidth of light source

Results
Tree shrew CTS1 normal RE
Rat CR312 normal RE
Rat CR337 normal RE
Rat CR312 glaucomatous LE
Tree shrew glaucomatous LE
Rat CR337 glaucomatous LE
  • Discussion
  • Glaucoma introduced in left eye
  • Optic atrophy and morphological changes seen in
    left eye
  • Tree shrews and rats retinas differ
  • Hyaloid artery interfere with ONH imaging in tree
    shrews
  • Orbital fats caused a layer oil film, disrupting
    images
  • Careful handling of retinas required
  • Hyaloid artery interferes with imaging
  • Detection of glaucoma in animals retina
    correspond to that in human
  • Future outlook
  • Visualise structure without sacrificing animal
  • Extend knowledge to human
  • Beneficial in early detection of glaucoma
  • Pick up other ocular diseases due to early
    morphological changes
  • Applies to other areas of biomedical research
  • Acknowledgements
  • I would like to thank Prof Wolfgang, Dr Boris
    Povazay and the OCT team for their help and
    guidance throughout the 6 weeks of the placement
    which made the experience amazing
  • I would also like to extend my upmost gratitude
    to CUROP and Cardiff University for funding me
    during the 6 weeks of placement
  • Reflections
  • Provide an insight to research work
  • Exposed to new technology
  • Rewarding, fruitful experience
  • Allowed to be part of a promising research team

References Figure 5 taken from http//www.healthye
yes.org.uk/uploads/pics/Eye-1.jpg and
http//www.e-sunbear.com/images/glopticnerve.jpg
and http//www.answersingenesis.org/Home/Area/Maga
zines/tj/images/v13n1retina3.gif Figure 6 taken
from http//www.meei.harvard.edu/patient/images/op
tic-nerve-head.jpg Figure 7 taken from
http//www.intecheye.com/Upload/glaucoma1.jpg
  • Limitations of OCT
  • Optical imaging restricted to surface tissues but
    not affected in the eye
  • Less penetration than ultrasound
  • Optical artefacts interfere with quality of images
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