INTRODUCTION:
The
electroretinogram (ERG) represents a record of the action potential produced by
the retina on stimulation by light of adequate intensity.
The test is useful as it provides a fast and non-invasive assessment of the electrophysiology of the retina.
The
electroretinography recording is usually made by using an active electrode
placed on the cornea or on the skin, just below the lower eyelid and a
reference electrode positioned on the forehead of the subject.
COMPONENTS OF ERG:
The potential
between the electrodes is amplified and displayed in the form of a graph. The
normal ERG is biphasic. It consists of the following waves:
a-wave: It is
the initial fast negative deflection produced by the photoreceptors, with a
peak (implicit time) of 100 msec.
b-wave: It is
the next slower positive deflection, having a higher amplitude. It is generated
from fluxes of potassium ions, within and surrounding Muller cells. However, it
is directly dependent on photoreceptor function and is a reflection of
photoreceptor integrity.
The amplitude
of b-wave is measured from the trough of the a-wave to the peak of b-wave. It
increases with dark adaptation, as well as, increased light stimulus.
The b-wave is subdivided into two sub-components:
b-1 represents rod and cone activity
b-2 represents cone activity alone
Rod and cone
activity can be singled out by special techniques.
The normal ERG
consists of 5 recordings. The first 3 are elicited after 30 minutes of dark
adaptation (scotopic), the last 2 after 10 minutes of moderately bright
diffuse illumination (photopic). In children it is difficult to dark
adapt for 30 minutes, so dim light (mesopic) can be used.
|
SCOTOPIC
ERG |
Rod |
Elicited
with very dim flash of white light or a blue light, resulting in a large
b-wave and a small or non-recordable a-wave |
|
Combined
Rod and Cone responses |
Elicited
with a very bright white flash resulting in a prominent a-wave and a b-wave |
|
|
Oscillatory
potentials |
Elicited by using a bright flash and changing the recording
parameters. The oscillatory wavelets occur on the ascending limb of the
b-wave and are generated by cells within the inner plexiform layer as a
consequence of inhibitory feedback loops involving primarily amacrine cells. |
|
PHOTOPIC
ERG |
Cone
responses |
They
are elicited with a single bright flash, resulting in an a-wave and a b-wave
with small oscillations |
|
Cone
flicker |
Used to
isolate cones by using a flickering light stimulus at a frequency of 30Hz to
which rods cannot respond. The amplitude and implicit time of the cone b-wave
are measured by this element. Cone responses can be elicited up to 50Hz in
normal eyes, beyond which individual responses are no longer recordable
(critical flicker fusion). |
TYPES OF ERG:
The ERG evoked
by a flash of light (flash ERG) is affected more by outer retinal
elements and is not typically abnormal in glaucoma. Flash ERG is the summed
electrical activity of different groups of retinal cells, in response to a flash
of light. The primary waveforms in the flash ERG are the a- and b-waves. These
arise predominantly from the outer and middle retinal layers respectively.
However, the flash ERG is rather a gross method to diagnose or monitor
glaucoma, since the condition is characterized by selective loss of retinal
ganglion cells (RGCs).
ERG related
studies have demonstrated no difference in a-wave, b-wave, and implicit time
between POAG and normal subjects. Some studies have demonstrated that these
parameters may be affected later in the disease, suggesting involvement of
outer or middle retinal layers as the disease progresses.
However, other
studies have shown the photopic negative response (PhNR) in primary open
glaucoma glaucoma (POAG) could be affected. This is a slow negative potential
that follows the b-wave in response to a photopic stimulus and originates from
the inner retina.
PhNR amplitudes
are found to be consistently smaller in POAG patients and correlate with the
mean deviation determined by static perimetry, even with mild visual field
sensitivity losses.
Another study
has shown that PhNR amplitudes correlate with decrease in function and
morphology of retinal neurons in eyes with OAG, indicating that inner retinal
function apparently declines proportionately with neural loss in glaucomatous
eyes.
The amplitude
of the PhNR has been shown to decrease with an increase in visual field defects
and is significantly correlated with the retinal nerve fiber layer thickness
(RNFLT) and the rim area of the optic disc as well as the cup:disc ratio.
ERGs can also
be evoked by providing a stimulus in the form of alternate gratings (e.g.
checkerboard stimuli) at a constant mean luminance. This is called Pattern-ERG (PERG).
It represents a more focal response from a specific area of the retina, being
stimulated. PERG is a direct and objective measure of RGC and optic nerve
functions.
A number of studies have reported PERG to have reduced amplitudes in glaucomatous individuals. PERG is found to be abnormal in early glaucoma and those ocular hypertensives who are prone to convert to POAG. This could prove useful in discriminating between those patients with ocular hypertension who will develop visual field loss and those who will not. These abnormal results have been recorded even one year prior to the development of visual field changes suggestive of conversion.
A study has
demonstrated that PERG amplitude correlates with RNFL thickness in early
glaucoma but not ocular hypertension.
Decreased
amplitude and increased peak latency reportedly correlate with increasing age,
paralleling the estimated normal loss of ganglion cells. Reduction in PERG is
also directly related to histologically defined optic nerve damage in a monkey
model.
Multifocal ERG (mfERG) permits simultaneous recording of multiple spatially
localized ERGs. mfERG permits topographic display of retinal function and
allows for much more detailed assessment of retinal function at specific areas
affected by disease.
It consists of
the same components as a standard ERG. Preliminary studies suggest that it does
not appear to correlate well with glaucomatous damage and may be able to detect
abnormalities before automated achromatic visual fields can show changes.
MfERG has shown
utility in assessing inner retinal function by identification of the optic
nerve head component (ONHC), which is of inner retinal origin and is thought to
arise in the vicinity of the optic nerve head. This component shows most
relevance to the detection of early glaucoma because it has been shown that its
propagation time correlates with the length of the ganglion nerve fibers and
thus seems to be dependent on the nerve fiber layer.
Studies have
demonstrated significant changes in the mfPERG of glaucoma patients, with
components of the mfPERG significantly decreased, most distinctly in the
central ring, and decreasing further with a progression of glaucoma stage.
Though
abnormalities can be readily detected in mfERG recordings from glaucomatous
eyes, the advantage of topographic analysis offered by the technique has not
proven important for glaucoma diagnosis.
CONCLUSION:
While
electrophysiological studies such as ERG showed early promise, but the
cumbersome instrumentation, lack of understanding and utility of the procedures
made this method go into relative obscurity in clinical practice. With newer
instruments and studies there is renewing interest in these modalities.
