Original Article

Multiplex PCR for Detection of Herpes Simplex Viruses
Type-1 and Type-2, Cytomegalovirus, Varicella-zoster

Virus, and Adenovirus in Ocular Viral Infections

Ahmed Nishat H1; MBBS, MD; Gita Satpathy1; MBBS, MD; Rohan Chawla2; MBBS, MD
Radhika Tandon2; MBBS, MD

1Ocular Microbiology, Dr. R P Centre, All India Institute of Medical Sciences, New Delhi, India
2Ophthalmology, Dr. R P Centre, All India Institute of Medical Sciences, New Delhi, India

ORCID:
Nishat Ahmed: https://orcid.org/0000-0002-1683-4275

Abstract

Purpose: Most common viruses causing ocular infections are Herpes Simplex
Viruses (HSV) type 1 and type 2, Cytomegalovirus (CMV), Varicella-zoster Virus
(VZV), and few strains of Adenovirus. Diagnosis of these infections through clinical
manifestations and using conventional methods has a number of limitations.
The purpose of this study was to develop a multiplex Polymerase Chain
Reaction (PCR) for simultaneous detection of all pathogenic viruses from ocular
infections.
Methods: Ten uniplex PCRs were standardized, two each for HSV type 1 (HSV-1) and
type 2 (HSV-2), CMV, VZV, and Adenovirus. Various multiplexing combinations of
above PCRs were put to finalize targets and reaction conditions enabling diagnosis of
all in a single reaction. The uniplex and multiplex PCRs were run for known positive and
negative controls, and samples from clinically suspected patients and healthy controls.
Results: Out of the 170 samples from suspected ocular infections, 24.7% were positive
by uniplex PCR and 22.9% were correctly identified by multiplex PCR. None of the
samples negative by uniplex PCRs was positive by the multiplex PCR. The sensitivity
and specificity of multiplex PCR compared to the commonly used uniplex PCRs as
gold standard was 92.86% and 100%, respectively. The prevalence of different viral
pathogens was 13.5% for HSV-1, followed by 5.9% for Adenovirus, 2.4% for VZV, 1.8%
for HSV-2, and 1.2% for CMV.
Conclusion: The establishment of multiplex PCR has found immediate application in
diagnosing ocular viral pathogens in a single reaction, thus saving time, manpower,
and resources by fivefold.

Keywords: Adenovirus; Cytomegalovirus; Herpes Simplex Virus; Multiplex Polymerase Chain
Reaction; Varicella-zoster Virus

J Ophthalmic Vis Res 2021; 16 (1): 3–11

© 2021 NISHAT ET AL. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY

KNOWLEDGE E 3

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Multiplex PCR for Ocular Viral Infections; Nishat et al

INTRODUCTION

It is estimated that by the year 2020, the
blind population in India will grow to 15
million and ocular infections will account
for 15% of the total burden.[1] Viruses can
cause a variety of ocular infections including
conjunctivitis, keratitis, keratoconjunctivitis, uveitis,
chorioretinitis, iridocyclitis, and acute retinal
necrosis syndrome.[2–7] Unattended/late treated
ocular infections especially with members of
Herpesviridae family, including Herpes Simplex
Virus-1 (HSV-1), Herpes Simplex Virus-2 (HSV-2),
Cytomegalovirus (CMV), Varicella-zoster Virus
(VZV), and few serotypes (1–4, 7, 8, 11, 19, 37, 53,
and 54) of Adenovirus can lead to loss of vision.[8, 9]
It is often challenging to determine the causative
agent, as there could be significant overlap
between the clinical features especially in the
early stages of the disease leading to misdiagnosis.
There is therefore a need to establish a prompt
diagnostic testing that is both rapid and sensitive
for an early detection and to determine the
choice of treatment.[4] The conventional methods
used for diagnosing ocular viral infections are
either less sensitive and/or specific, require
sophisticated equipment and infrastructure and/or
explicit expertise, or have a long turnaround
time. In recent decades, focus has been on
molecular diagnostics for such infections, in which
Polymerase Chain Reaction (PCR) has proven
to be a valuable technique. In this technique,
the target gene of interest, called nucleic acid
template, is amplified in a thermo-cycling reaction.
From a single template, billions of copies are
produced, which can then be identified by post-
amplification analysis. It overcomes the lower
sensitivity of conventional laboratory techniques
while maintaining specificity. In addition, it can also
be performed on limited patient-derived ocular

Correspondence to:

Ahmed Nishat H. MBBS, MD. Ocular Microbiology
Section, Dr. R P Centre, All India Institute of Medical
Sciences, New Delhi- 110029, India.
E-mail: drnishathussain@gmail.com
Received: 07-02-2019 Accepted: 22-05-2020

Access this article online

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DOI: 10.18502/jovr.v16i1.8243

specimen and is less time consuming, inexpensive,
and rapid.[2]

Multiplex PCR is a variant in which all viruses
in the differential can be diagnosed in a single
PCR, thus saving time and cost. The technique
works on the principle that different pairs of primers
are unique to different infectious agents and their
amplicon size varies in length so that the visual
difference is observed when PCR reaction product
is resolved on an agarose gel. It has an enormous
clinical value as it allows simultaneous detection
of multiple target organisms in a single reaction;
thus, it is more informative and requires very
less starting patient specimen. Further, there are
various technical advantages of using multiplex
PCR including rapid diagnosis, less cumbersome
procedure, cost effectiveness, and less time taken
to obtain results than conventional diagnostic
methods. It has increased accuracy of data
normalization and is subject to fewer human
pipetting errors.[10]

Standardization and establishment of multiplex
PCR for the diagnosis of ocular viral infection has
immense clinical and technical advantage. Hence,
this study was planned to standardize and establish
a multiplex PCR targeting all common ocular
viral pathogens for accurate and rapid laboratory
confirmation, thereby aiding in the implementation
of correct and timely treatment and to determine
the prevalence of different viruses as ocular
pathogens in our patient cohort.

METHODS

Ethics

Approval of the Institute Ethics Committee
was taken, and the procedures were done in
accordance with the Helsinki Declaration of 1975,
as revised in 2000. Written informed consent was
obtained from all patients and controls.

Study Design

The current prospective case–control study was
conducted over a duration of 21 months (July 2016
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How to cite this article: Nishat HA, Satpathy G, Chawla R, Tandon R.
Multiplex PCR for Detection of Herpes Simplex Viruses Type-1 and Type-
2, Cytomegalovirus, Varicella-zoster Virus, and Adenovirus in Ocular Viral
Infections. J Ophthalmic Vis Res 2021;16:3–11.

4 JOURNAL OF OPHTHALMIC AND VISION RESEARCH VOLUME 16, ISSUE 1, JANUARY-MARCH 2021

https://knepublishing.com/index.php/JOVR


Multiplex PCR for Ocular Viral Infections; Nishat et al

to March 2018) in the Ocular Microbiology section
of an apex healthcare institute of North India, which
caters to the tertiary healthcare requirements of
Delhi and nearby six to seven states.

Selection and Description of Participants

A total of 170 samples, clinically guided to
undertake laboratory diagnostic tests for viral
infections, were included as test samples. The
patients had various clinical manifestations.
Vitreous and aqueous aspirates were collected
in sterile Eppendorf tubes; and samples like
scrapings, tears, swabs, etc. were collected
in sterile Eppendorf tubes containing 1 ml of
phosphate buffered saline (PBS, pH 7.2). Maximum
numbers of samples received were corneal
scrapings (54), conjunctival swabs (45), and tears
(33). Fifty tear samples from individuals devoid of
any clinical symptoms of ocular infections were
included as controls.

DNA Extraction

DNA extraction was done using the QIAamp
DNA extraction kit (QIAGEN, Qiagen Str. 1,
40724 Hilden, Germany), strictly following the
manufacturer’s instructions. As the quantity of
ocular specimens was very little, elution of DNA
was done in 60 µl of elution buffer. Extracted DNA
samples were stored at 0–4°C until processed.

Standardization of Multiplex PCR

Published primers unique and highly specific for
HSV-1, HSV-2, CMV, VZV, and Adenovirus were
used for standardizing uniplex PCRs. A total of
10 uniplex PCRs were standardized, two each for
HSV-1, HSV-2, CMV, VZV, and Adenovirus.[11–13]
Results of uniplex PCRs were checked in control
strains of all viruses, non-ocular stored clinical
specimens positive for different study viruses,
and also in extracted DNA from cultures of
Staphylococcus, Pseudomonas aeruginosa,
Acanthamoeba species, Aspergillus flavus, and
Fusarium species.

The uniplex PCRs were then run at different
annealing temperatures and with some variations
of cycle conditions to obtain the annealing
temperature and cycle conditions suitable
for all five study viruses. Various multiplexing

combinations of above PCRs were put to make
it possible to diagnose all the above five viruses
in a single reaction. The five targets, annealing
temperature, and reaction conditions which were
giving best results for all viruses in a single reaction
were finalized. The multiplex reactions were run
with control strains of all viruses, non-ocular
clinical specimens positive for different study
viruses, and DNA extracted from the cultures of
Staphylococcus, P. aeruginosa, A. species, A.
flavus, and F. species. All the results of uniplex
and multiplex PCRs were finally verified in stored
DNA of ocular specimens with known results.

Subsequently, for all clinical samples and
controls, five uniplex PCRs (one for each virus) and
one multiplex was run. DNA of ATCC-VR-539D,
HSV-1 strain McIntyre; ATCC-VR-734D, HSV-2 strain
G; OKA vaccine strain of VZV; and pooled extracted
DNA positive for CMV and Adenovirus from clinical
samples were used as positive controls in each
run. Autoclaved MilliQ water controls were used as
negative controls in each run. ATCC strains were
purchased through LGC Promochem India Private
Limited, Bangalore, India.

The details of primers for the five selected
targets for the multiplex PCR are shown in Table
1. Both the uniplex and multiplex PCR amplification
reactions were conducted in 25 µl volumes. The
reaction mixture consisted of dNTPs (200 mM) –
0.5 µl, 10X buffer – 2 µl, MgCl2 – 1.2 µl, forward
primer – 1 µl, reverse primer – 1 µl, Taq DNA
polymerase 1U – 0.2 µl, test DNA – 2 µl, and
autoclaved MilliQ water – 12.1 µl made up to 25
µl. The amplification profile chosen was as follows:
initial denaturation at 95°C for 5 min, followed by 40
cycles of denaturation at 95°C for 30 sec, annealing
at 55°C for 35 sec, extension at 72°C for 40 sec, and
final extension at 72°C for 10 min.

Electrophoresis and Documentation

Following the PCR, the amplicons were resolved
on a 1.5% agarose gel. Visualization was done
with the aid of ethidium bromide (0.5 µg/ml) under
ultraviolet illumination using gel documentation
system – Biospectrum R 810 Imaging System – UVP
(2066 W. 11th St., Upland, CA 91786, USA). Figures
1a, 1b, and 1c show the gel images of positive
controls and positive test samples by multiplex
PCR.

Results of uniplex and multiplex PCRs were
entered in Microsoft Excel sheets (Microsoft𝑅 Office

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Table 1. Details of primers for the five selected targets for the multiplex PCR

Name Primers Region Sequence (5’-3’) Size

HSV 1 HSV 1-F RL-2 TGGGACACATGCCTTCTTGG 147 bp

HSV 1-R RL-2 ACCCTTAGTCAGACTCTGTTACTTACCC

HSV 2 HSV 2-F gp-D GTCGGTGTGGTGTTCGGTCATAAGCT 276 bp

HSV 2-R gp-D GGCTGAATCTGGTAAACACGCTTC

CMV CMV-F pol and gp-B CACGGCCGCCACCAAGGT 392 bp

CMV-R pol and gp-B AGTGGTTGGGCAGGATAAA

VZV VZV-F gp ATCGCGGCTTGTTGTTTGTCTAAT 355 bp

VZV-R gp GGGCGAAATGTAGGATATAAAGGA

Adenovirus Adenovirus-F Hexon GCCGCAGTGGTCTTACATGCACATC 308 bp

Adenovirus-R Hexon CAGCACGCCGCGGATGTCAAAGT

RL, long repeat region; gp, glycoprotein region; pol, DNA polymerase gene

Table 2. Results of uniplex and multiplex PCRs in test samples

Pathogenic virus Numbers identified by uniplex
PCR

Numbers
identified by

multiplex PCR

HSV-1 23 22

HSV-2 03 03

CMV 02 02

VZV 04 03

Adenovirus 10 09

Total Positive 42 39

Negative 128 131

Excel𝑅 2007 [12.0.4518.1014] MSO [12.0.4518.1014]).
Sensitivity, specificity, positive and negative
predictive values, and accuracy of multiplex PCR
was calculated with uniplex PCRs as gold standard.

RESULTS

Controls

Both uniplex and multiplex PCRs were correctly
able to identify the viruses from stored DNA of
positive ocular and non-ocular samples. None
of the DNA from non-viral ocular pathogens –
Staphylococcus, P. aeruginosa, A. species, A.
flavus and F. species – was positive for any of the
viruses by uniplex or multiplex PCR. None of the
50 control samples from healthy eyes were positive
for any of the viruses by uniplex or multiplex
PCR.

Clinical Samples

Over the duration of 21 months, 170 specimens
from clinically suspected ocular viral infections
were received. Uniplex and multiplex PCRs for
HSV-1 and HSV-2, CMV, VZV, and Adenovirus were
performed for all patients’ specimens.

Table 2 shows the results of uniplex and
multiplex PCRs in test samples. Out of the 170
samples from cases of suspected ocular infections,
42 (24.7%) were positive for some of the five viruses
tested by uniplex PCR. Multiplex PCR was able to
correctly detect 39 out of 42 positives of uniplex
PCRs (22.9% of 170). None of the samples were
positive for more than one virus. None of the
samples negative by uniplex PCRs was positive by
the multiplex PCR. Thus, the sensitivity, specificity,
positive predictive value, negative predictive value,
and accuracy of the multiplex PCR was 92.86%,
100%, 100%, 97.71%, and 98.24%, respectively.

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Table 3. Results of uniplex and multiplex PCRs from patients with different clinical diagnosis

Clinical diagnosis Number of specimens
received

Positive by
uniplex PCR

Positive by
multiplex PCR

Conjunctivitis 41 17 16

Keratitis 81 12 11

Blepharitis 3 0 0

Lid and periocular vesicles 5 4 3

Uveitis 5 2 2

Chorioretinitis 5 2 2

Endophthalmitis 3 0 0

Others 27 5 5

Total 170 42 39

The prevalence of different viral pathogens
causing ocular infections as determined by the PCR
was found to be 13.5% for HSV-1 (23 out of 170
cases positive), followed by 5.9% (10 positive) for
Adenovirus, 2.4% (four positive) for VZV, 1.8% (three
positive) for HSV-2, and 1.2% (two positive) for CMV
(Table 2).

Table 3 and Figure 2 show the distribution
of samples received from patients with different
clinical diagnoses. Maximum samples were from
patients having keratitis, followed by conjunctivitis.
Viral infections could be diagnosed using multiplex
PCR in 60% of patients having lid and periocular
vesicles. Viral etiology could also be clinched in
39% of conjunctivitis and 40% each of uveitis and
chorioretinitis patients using the multiplex PCR.

Maximum positivity was observed in vesicle fluid
and scrapings (60%), followed by lid scrapings
(33.3%), conjunctival swabs (31.1%), and vitreous tap
(30%). The positivity in tear samples was found to
be 24.2% (Figure 3).

DISCUSSION

Ocular viral infections can range from simple self-
limiting discomfort to possibly vision challenging
manifestations. The clinical manifestations of such
infections are not specific for a particular virus;
frequently, the differential includes a number of
viruses. There often is an overlap of signs and
symptoms with non-viral infections and some non-
infective conditions. This is more common in
tertiary care centers where the patients often
come after partial treatment performed outside,
have some underlying immune-compromise, or

have some complications of the infection. Most
common viruses causing ocular infections are HSV-
1, HSV-2, CMV, VZV, and Adenovirus, which are
difficult to differentiate by clinical findings alone;
nevertheless, the differentiation is important as
it determines the choice of treatment.[2] Late or
inappropriate treatment of such infections due to
delayed diagnosis can compromise the vision of
the patient. PCR is now a popular diagnostic test for
viral infections; however, its application is limited in
clinical situations where the differential diagnosis
takes account of several pathogens. Running a
PCR for each pathogen in the differential is a
time- and resource-consuming process; moreover,
each extra reaction has its own share of errors;
and sometimes it is not possible to do many
reactions as the specimen size is minute in ocular
infections. There is a dearth of an accurate,
rapid, and cost-effective diagnostic test which
can be undertaken on limited ophthalmic sample
volume.

A multiplex PCR was thus standardized targeting
HSV-1, HSV-2, CMV, VZV, and Adenovirus. This
enabled the diagnosis of all five common ocular
viral pathogens in a single reaction. The sensitivity
and specificity of the multiplex PCR was found to
be 92.5% and 100%, respectively. The multiplex
PCR was made sensitive for diagnosing ocular viral
infections by multiplexing the five most common
pathogenic viruses. Specificity was established by
simultaneously using uniplex PCRs in all clinical
specimens and controls; also, the multiplex PCR
did not show any false positivity in DNA from non-
viral pathogens. The multiplex PCR was found to be
useful in tear samples, which are the least invasive

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Figure 1. Gel images of positive controls and positive test samples by multiplex PCR. (a) Multiplex PCR simultaneously detecting
all five viruses, (b) Ocular specimens positive for HSV-2 and VZV by multiplex PCR, and (c) Ocular specimens positive for CMV,
VZV, HSV-1, and Adenovirus by multiplex PCR.

of ocular specimens, showing viral detection in
24.2% of tear samples received. Furthermore, the
test was able to clinch diagnosis in 40% of uveitis
and chorioretinitis cases, establishing the etiology
of which is otherwise very difficult and time-
consuming.

In the current study, we also looked for the
prevalence of different viruses as ocular pathogens

in our patient cohort, and for any asymptomatic
carriage in control group.

The overall positivity for viral pathogens in
clinically suspected ocular viral infections as
detected by uniplex PCR was 24.7% with HSV-
1 being the most common (14.4%), followed by
Adenovirus (5.9%). None of the healthy controls
were positive for any of the viruses.

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Figure 2. Distribution of specimens received and results of uniplex and multiplex PCRs from patients with different clinical
diagnosis.

Our results are comparable to similar studies
done in India and abroad.

A study from Japan utilizing multiplex PCR for
the detection of HSV-1, HSV-2, CMV, and VZV
in different ocular infections has reported the
multiplex PCR to be as good as uniplex PCRs
for each of the viruses. They have reported a
positivity of 57.6% in clinically suspected ocular
viral infection cases. Amongst the positives, HSV-
1 was the most common (68.4%), followed by VZV
(31.6%).[13] Sugitha et al from Japan have recently
described the results of utilization of a multiplex
PCR for the detection of eight herpes viruses
and the parasite Toxoplasma gondii in cases
with uveitis and endophthalmitis. They reported
sensitivity and specificity of 91.3% and 98.8%,
respectively. The positivity in their study group was
34%, with CMV and VZV being the most common
viral pathogens.[14]

Elnifro et al in their study in United Kingdom
tested a multiplex PCR for detecting HSV,
Adenoviruses, and Chlamydia in eye swabs.
Although they observed a 10-fold fall in the

sensitivity of detection limit using multiplex PCR,
there was no significant difference in the diagnostic
sensitivity of multiplex PCR when compared to that
of individual uniplex PCRs.[15]

Another similar study from India reported
multiplex PCR for HSV, VZV, and CMV in ocular
specimens. The authors have not compared
their results with uniplex PCRs in all samples;
however, they have established detection
limits of multiplex PCR using several dilutions
of standard strains. The sensitivity of uniplex
PCR for HSV, VZV, and CMV was 4, 4, and
6 PFU/ml, respectively, while that of multiplex
PCR was 4, 4, and 12 PFU/ml, respectively. The
authors have also established specificity using
diverse DNA samples derived from non-viral
infections and non-infectious conditions of the
eyes. The most common viral infections found
were HSV (83.6%), followed by VZV (2%) and CMV
(1.4%).[12]

The most recent study is from United States,
in which Bizpo et al have reported results of
a qualitative multiplex real-time PCR for the

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Figure 3. Sample-wise distribution of results of uniplex and multiplex PCRs.

identification of common pathogens causing
uveitis. They have targeted viruses HSV-1, HSV-2,
VZV, CMV and parasite T. gondii and have found
the multiplex real-time PCR to be highly specific
with a limit of detection of 20 genome copies for
viral pathogens and 200 genome copies for T.
gondii.[16]

There are a few limitations of the study. We
have not found the detection limit in terms of
genome copy number of uniplex and multiplex
PCR for each virus, which would be a better
marker of sensitivity of the test. Also, involvement
of samples from other ophthalmic centers and
inclusion of bioinformatics and in silico analysis
would have added weight to the results of the
present study.

To conclude, the present study has shown
that the multiplex PCR targeting five common
viral infections can serve as a valuable
diagnostic tool for ophthalmic viral infections.
It reduces the turnaround time to diagnose
specific viruses, and also the chances of errors
associated with putting multiple reactions; at

the same time saving on hands on work and
cost of diagnosis. The study has also thrown
light on current epidemiology of ocular viral
infections.

The understanding of current pattern of ocular
viral infections and utilization of multiplex PCR for
diagnosis can go a long way in improving the
management of patients having viral infections of
the eyes.

Acknowledgements

The authors are thankful to the Research Section,
All India Institute of Medical Sciences, New Delhi,
for providing the institutional research grant for
conducting this study. They are also grateful to Mrs.
Shailamma Joseph for her technical assistance.

Financial Support and Sponsorship

The study was funded by the ’Institutional Research
Grant’ from All India Institute of Medical Sciences,
New Delhi, India.

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Multiplex PCR for Ocular Viral Infections; Nishat et al

Conflicts of Interest

There are no conflicts of interest.

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