Original Article

Clinical Evaluation of the 3nethra Aberro Handheld
Autorefractometer

Selvamani Perumal1, MS; Surya Venkatramanan1, BTech; Venkatramanan RJ1, MBA; Jayanthi T2, PhD; Jai
Adithya2, BTech; Anjaly Abraham2, BTech; Henna Cherian2, BTech

1Forus Health Pvt Ltd, Banashankari, Bangalore, Karnataka, India
2Department of Biomedical Engineering, SRM Institute of Science and Technology, Kattankulathur, Chennai, Tamil Nadu, India

ORCID:
Selvamani Perumal: https://orcid.org/0000-0002-4579-6693
Venkatramanan RJ: https://orcid.org/0000-0003-3674-8515

Abstract

Purpose: To evaluate the 3nethra aberro auto refractometer device as an
alternative tool for quick and reliable measurement of refractive errors and to
compare it with the gold standard subjective refractive error measurement.
Methods: Refractive errors were measured using both subjective refraction and
the 3nethra aberro handheld autorefractometer. The refractive measurements
were converted into equivalent vector notations of spherical equivalent and
Jackson cross-cylinder measurements J0 & J45. The resultant power vectors
were compared with subjective measurements.
Results: This clinical study comprised 60 subjects (22 male and 38 female; with a
mean age of 34 ± 16 years). Data, when compared with the subjective refraction
measurements, resulted in 90% of power vectors values in both left and right
eyes being the same in the 3nethra aberro handheld autorefractometer and
the subjective measurement. The refractive error measurements also had an
agreement of 70% and 90% when the range of diopter was between ±0.25
and ±0.5D, respectively. When the Bland-Altman’s plot analysis was performed,
about 98% of data lied within the ±2 standard deviation variation. An average
correlation between the two methods of error measurement was 0.74, and the
paired t-test showed P > 0.05 for all the power vectors except for the spherical
equivalent in the right eye.
Conclusion: The 90% agreement between the error measurements done by
two methods indicates that the 3nethra aberro handheld autorefractometer can
function as an alternative for the time-consuming subjective refractive error
measurement.

Keywords: Aberro Autorefractometer; Non-mydriatic; Pupil Diameter; Refractive Index;
Subjective Refractive Error; Vision; Wavefront Technology

J Ophthalmic Vis Res 2022; 17 (4): 536–542

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3nethra Aberro-Autorefractometer ; Perumal et al

INTRODUCTION

Visual impairment due to uncorrected refractive
errors may lead to serious consequences. In a
survey conducted in 2004, the World Health
Organization (WHO) reported that globally 153
million people above the age of five years were
visually impaired due to uncorrected refractive
errors, of whom 8 million eventually experienced
blindness.[1] This report emphasizes the importance
of correcting refractive errors. The report also
highlights that the reason for uncorrected refractive
error is the lack of screening. The gold standard
clinical method available for correcting refractive
errors is subjective refraction (SR) measurement.
The routine procedure of SR is time-consuming
and also entirely dependent on the patient’s ability
to read the Snellen chart in conjunction with
the skill level of the operator and hence cannot
be applicable for mass screening. Techniques
involving the use of auto refractometers, which
are portable and allow measurement under
non-cycloplegia conditions, are considered to
be an alternative for SR. However, the auto
refractometer seems unreliable for higher-order
aberrations.[2, 3] The auto refractometer measures
the overall refractive index of the eye over a small
region of the pupil. Hence, autorefractometer
measurements seems to have more deviation
from the SR measurements.[4, 5] Recently, the
3nethra aberro handheld autorefractometers
(AHAR), which work based on the Shack-Hartmann
Wavefront technology have been introduced. The
aberration is reconstructed using the Zernike
polynomial of the reflected light pattern and is a
preferred technique for measuring refractive errors
in LASIK surgery. It is observed that the vision will
be almost back to normal after Wavefront-guided
LASIK surgery due to the ability to precisely
measure the refractive errors.[6, 7] The accuracy of
the technique when measuring refractive errors

Correspondence to:

Venkatramanan RJ, MBA. Forus Health Pvt Ltd,
Banashankari 560070, Bangalore, India.
Email: rjv.ramanan@forushealth.com
Received: 22-06-2021 Accepted: 21-03-2022

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DOI: 10.18502/jovr.v17i4.12314

in both high- and low-order aberrations along
with the quick results that are produced has
familiarized the use of this option when performing
visual examinations.[8, 9] As a consequence, the
aim of the study is to propound the use of
AHAR measurement as a crucial tool for measuring
refractive errors in mass screening.

METHODS

The device referred to as 3nethra AHAR was used
in the study. The 3nethra AHAR is a device which
works based on Shack-Hartmann Wavefront
sensing technology. Some of the technical
specifications of the device include the following:
the spherical measurement range is from –14D to
+14D and the cylindrical measurement range is
from –7D to 0D both in increments of 0.25D; the
axis measurement ranges from 0 to 180 degrees.
In addition, the minimum pupil diameter that can
be measured using the device is about 2.5 mm. It
also has a fast measurement time of fewer than 5
sec per eye.

The subjects for the study were selected
randomly from the outpatient unit in the
Department of Ophthalmology of a private
hospital. Informed consent was obtained from
all the participants included in the study. Our
inclusion criteria were all subjects from age 5 to 60
years with refractive errors. The clinical exclusion
for the study were people with acute cataract,
severe eye infections, and those who underwent
surgeries to extract cataracts or for any refractive
correction. A total of 60 subjects were included
in the study, 22 male and 38 female with a mean
age of 34 ± 16 years. The patients were seated
comfortably and asked to focus on the target at 6
m. The refractometry measurement was performed
under non-cycloplegic conditions using the digital
handheld 3nethra AHAR. The sphere, cylinder,
and cylindrical axis measurements were taken for
each patient. All the measurements were carried
out in the same room with uniform illumination for
both the right and left eyes. The pupil diameter
was also measured using the same device.

This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and
reproduction in any medium, provided the original work is properly cited.

How to cite this article: Perumal S, Venkatramanan S, RJ V, T J,
Adithya J, Abraham A. Clinical Evaluation of the 3nethra Aberro
Handheld Autorefractometer. J Ophthalmic Vis Res 2022;17:536–
542.

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3nethra Aberro-Autorefractometer ; Perumal et al

Table 1. Comparison of AHAR and SR measurements.

Sl. No Right eye Left eye

Power vectors SPE M J0 J45 SPE M J0 J45

Less than SR 11 1 1 12 2 0

Equal to SR 46 59 58 47 57 60

Greater than SR 3 0 1 1 1 0

AHAR, aberro handheld autorefractometers; SR, subjective refraction; SPE, spherical equivalent

 

Figure 1. The Bland-Altman plots for comparing the SR and AHAR observations in the right and left eyes for SPE. 95% limits of
the agreement are indicated by the upper and lower dashed line, and the mean is indicated by a solid line.

The customary clinical SR measurements were
performed using a trained optometrist (who was
also masked from the AHAR measurements) with
a usual set of lenses and the placement of the
Snellen visual acuity chart at 20 ft (6 m). Based on
their visual acuity, the prescription was made.

RESULTS

The evaluations were performed under non-
cycloplegic conditions for both the 3nethra AHAR
and SR readings. All the power measurements
obtained using both methods, SR and 3nethra
AHAR, were converted into power vector notations

spherical equivalent (SPE M) and vertical and
oblique cylindrical vectors (J0 and J45) using
the method proposed by Thibos et al.[10, 11] The
power vector notations facilitate statistical analysis
to perform an algebraic operation on the eye’s
refractive index in an orthogonal 3-D base. The
conversion was done for both SR and 3nethra
AHAR measurements as follows:

SPE M = sphere + cylinder/2

J0 = –(cylinder/2) × cos (2 x-axis)

J45 = –(cylinder/2) × sin (2 x-axis),

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3nethra Aberro-Autorefractometer ; Perumal et al

Table 2. Agreement of the AHAR with SR power vector errors in both eyes.

Categories Right eye agreement with SR Left eye agreement with SR

SPE M (%) J0 (%) J45 (%) SPE M (%) J0 (%) J45 (%)

<0.25 42 83 85 53 80 90
<0.50 80 98 95 77 93 100

SR, subjective refraction; SPE, spherical equivalent

Table 3. Agreement of the AHAR with SR errors in both eyes (compound representation).

Right eye agreement with SR Left eye agreement with SR

Sphere (%) Cylinder (%) Axis (%) Sphere (%) Cylinder (%) Axis (%)

73 (<0.25) 78 83 72 78 77

85 (<0.50) 88 87 88 87 80

AHAR, aberro handheld autorefractometers; SR, subjective refraction

where the sphere, cylinder, and axis
measurements were obtained from the SR and
AHAR measurements.

The descriptive statistical analysis was
performed after the conversion. As indicated
in Table 1 in the right eye, 6% of eyes had an AHAR
reading less than the SR, 90.6% of the eyes had
the same value in both AHAR and SR, and 1.6% of
the eyes had a greater value than SR. Replicating
the calculation in the left eye, 6.4% of the eyes
had an AHAR value less than the SR, 90.9% eyes
had the same value in both AHAR and SR, and
about 0.5% of eyes resulted with greater values
than the SR. Table 2 illustrates the agreement
between the two methods based on the diopter
of error measured. Table 3 indicates the same in
compound numbers. As indicated, in the range
of ±0.25D, there was about 70% agreement
between the two methods in the right and 74%
in the left eyes. Correspondingly in the range of
±0.5D, the agreement between the AHAR and SR
measurements were 91% and 90% in the right and
left eyes, respectively.

The comparison of the mean and standard
deviation of the measurements observed from
the two methods was analyzed using Bland-
Altman plots. Figure 1 depicts the Bland-
Altman plots for the three power vectors. It
again shows the agreement between the SR
and AHAR measurements. Visual analysis
reveals that the majority of the readings

were within the ±2 standard deviation range
and consistently scattered around the mean
value.

Correlation

The AHAR measurements are taken with ±0.25D
accuracy while the SR measurement is made
with a resolution of ±0.5D considering the eye
accommodation. The correlation and paired t-test
were performed on the measurements. Figure
2 shows the regression plots for the three
measurements (SPE M, J0, and J45).

The statistical analysis of the observations is
indicated in Table 4. The average correlation of
0.72 is achieved between the power vectors at
0.25D for both right and left eyes as indicated in
Table 2. The P-value being greater than 0.05 in the
compared power vectors indicates that the errors
are similar, not rejecting the null hypothesis. Hence
the power vectors are the same in both methods.
The non-agreement of the errors in SPE M in the left
eye might be due to the ±0.25D margin for error by
the device in 3nethra AHAR, but it is not considered
in SR. All statistical significance was set at 0.05, and
the analysis was done using Microsoft Excel 2010.

DISCUSSION

Numerous related studies have been done on the
applicability of using autorefractometers versus SR

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3nethra Aberro-Autorefractometer ; Perumal et al

  

 
 

  

Figure 2. The correlation of the three power vectors in both the eyes.

Table 4. Statistical analysis of the power vector errors in SR and 3nethra AHAR.

Power vector Device Correlation between AHAR & SR Paired t-test P-value

Right eye Left eye Right eye Left eye

SPE M SR 0.96 0.95 P > 0.05 P < 0.05
AHAR

J0 SR 0.85 0.95 P > 0.05 P > 0.05
AHAR

J45 SR 0.85 0.95 P > 0.05 P > 0.05
AHAR

AHAR, aberro handheld autorefractometers; SR, subjective refraction; SPE, spherical equivalent

in assessing refractive errors, and the authors have
agreed to the more reliable performance of AR
measurements as compared to SR. In a study on
708 participants by Nicholas et al, AR was mostly
preferred by patients rather than by the visual
acuity results. The authors also suggest that using
AR is advantageous in rural health centers which
can be used by minimally trained technicians.[12]
Samanth et al highlight the superior performance
of autorefractometers in the study conducted using
a Nidek OPD scan III.[13] In the clinical evaluation
of the L80 auto refractometer, Einat et al conclude

that an autorefractometer is a reliable tool for
optometric practices.[14]

As an advancement to the technology of the
autorefractometers, the Wavefront technology is
efficient in creating the reconstruction of the
Zernike polynomial pattern in both high- and
low-order aberrations for individual patients.[15, 16]
Numerous related studies have been done on the
applicability of using autorefractometers versus SR
in assessing refractive errors, and the authors have
agreed to the more reliable performance of AR
measurements as compared to SR. In a study on

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3nethra Aberro-Autorefractometer ; Perumal et al

708 participants by Nicholas et al, AR was mostly
preferred by patients rather than by the visual
acuity results. The authors also suggest that using
AR is advantageous in rural health centers which
can be used by minimally trained technicians.[12]
Samanth et al highlight the superior performance
of autorefractometers in the study conducted using
a Nidek OPD scan III.[13] In the clinical evaluation
of the L80 auto refractometer, Einat et al conclude
that an autorefractometer is a reliable tool for
optometric practices.[14]

The agreement of the 3nethra AHAR
measurement with the SR in 90% of the eyes
validates the use of the device for direct
prescription after assessment. The results suggest
that the 3nethra AHAR show good agreement
with the SR error measurements. The 3nethra
AHAR refractive errors measured can be used for
direct prescription ordering in cases where the
SR may be time-consuming. The 3nethra AHAR
is also able to provide the measurement of pupil
diameters along with the refractive errors. The
functionality of this autorefractometer supports
the diagnosis of pathologies related to pupillary
muscles. With varying illumination, the functions of
pupillary diameters’ relationship can be studied.
The 3nethra AHAR measurements allow for the
ease of repeated measurements as compared
to SR under non-cycloplegic conditions. The
use of 3nethra AHAR measurements is practical
when assessing children who tend to be restless
while being examined. The rapid assessment
characteristics of the 3nethra AHAR may enable
the technology for use in mass screening and
replacing the SR measurements for refractive
errors.

Financial Support and Sponsorship

None.

Conflicts of Interest

None declared.

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