263 Vol. 35, No. No. 4, Oct – Dec, 2019 Pak J Ophthalmol

Original Article

The Efficacy and Safety of 0.3%
Acetylcysteine Eye Drops in Filamentary
Keratitis

Sameera Irfan

Pak J Ophthalmol 2019, Vol. 35, No. 4

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
See end of article for
authors affiliations

…..………………………..

Correspondence to:
Sameera Irfan
Consultant
EnVision” Squint &
Oculoplastics Centre
Email: Sam.irfan48@gmail.com

…..………………………..

Purpose: To determine the safety and efficacy of 0. 3% Acetylcysteine eye

drops for the resolution of symptoms and signs of filamentary keratitis.

Study design: Quasi experimental study

Place & Duration of Study: This study was conducted at a tertiary care centre
(Envision, Squint & Oculoplastics Centre, Lahore) from April 2016 to October
2018.

Material and Methods: Fifty two consecutive cases (104 eyes) with mild to
severe filamentary keratitis, from 9-72 years (mean 49 ± 8.6) were included.
Cases with active ocular surface infection, uveitis, recent ocular surgery (<1
month) and pregnant/lactating patients were excluded. All cases were prescribed
lubricants, anti-inflammatory therapy (Tacrolimus skin cream 0.03%) and
tetracycline eye ointment for meibomian gland disease (MGD). Alternate cases
were divided into two equal groups of 26 cases; Group A received Acetylcysteine
eye drops 0.3%, four times daily, Group B cases received placebo eye drops
(distilled water in a bottle). Clinical symptoms on ocular surface disease index
(OSDI), corneal filaments, corneal fluorescein staining, Tear Film BUT and
Schirmer’s test were recorded at the beginning of the study and every two
weeks, for the next 12 weeks.

Results: Primary Outcome Measure was reduction of symptoms (OSDI score)
and absence of filament formation after treatment. The patients were followed-up
for a mean duration 12 ± 2 weeks. A marked subjective and objective
improvement (100%) was noted in all cases that received Acetylcysteine 0.3%
eye drops as compared to the placebo group.

Conclusion: Acetylcysteine 0.3% eye drops efficiently dissolve filaments and

offer quick resolution of symptoms even in severe cases of filamentary keratitis.

Key words: Filamentary keratitis, dry eyes, Acetylcysteine eye drops, mucolytic
agents.

ilamentary keratitis is a chronic, recurrent and
functionally debilitating condition in which
mucous strands or filaments are present over

the ocular surface. With each blink, the eyelids pull
upon the filaments and the traction/pull exerted on
the underlying corneal epithelium results in a lot of
ocular discomfort, pain and a constant foreign body
sensation in the eye1. It occurs in association with a

number of ocular surface diseases like Sjögren
syndrome (SS), non-Sjogren’s Dry eyes syndrome
(non-SS), Stevens Johnsons syndrome, vitamin A
deficiency, lacrimal gland tumour/dacryo-adenitis,
superior limbic keratoconjunctivitis, chronic Vernal
keratoconjunctivitis, post-herpetic keratitis, recurrent
corneal erosions, neurotrophic keratitis, thyroid eye
disease (TED), facial palsy, bullous keratopathy, and

THE EFFICACY & SAFETY OF 0.3% ACETYLCYSTEINE EYE DROPS IN FILAMENTARY KERATITIS

Pak J Ophthalmol Vol. 35, No. 4, Oct – Dec, 2019 264

prolonged patching following ocular surgery.

Normally, there is a certain fixed ratio of aqueous:
mucin in the tear-film2. The mucin molecules float
freely in the aqueous component of the tear-film and
act as scavenger molecules, and secondly, it forms a
smooth, uniform coating over the glycocalyx of the
corneal apical cells thus making the normally
hydrophobic cornea hydrophilic, and allow the
aqueous component of the tear-film to spread
uniformly over the cornea.

The basic mechanism for filament formation is an
increased ratio of mucin to aqueous. Excess mucin
accumulates in the lower conjunctival fornix and is
joint together by disulphide bonds, thereby forming
mucous strands. The free mucin molecules are no
longer available to coat the glycocalyx over the apical
corneal epithelial cells so the corneal surface becomes
hydrophobic. The reduction of aqueous component
increases the osmolarity of the tear-film; the increased
concentration of solutes in the tear-film produce
chemical inflammation of the ocular surface. This
affect is exaggerated in the hot, dry climate, as a part
of the ageing process (androgen deficiency) and in
diabetes. The hyper-osmolar tears lead to sloughing of
the desiccated corneal surface epithelial cells thus
producing epithelial defects that act as high-energy
pits or a nidus to which mucous strands adhere firmly.
The corneal epithelium grows around the mucous to
form a filament. In addition, the inflammatory
cytokines and enzymes released from eosinophils and
lymphocytes in VKC, Sjogrens syndrome, viral
keratitis etc, further increase the osmolarity of the tear
film, thereby creating a chronic inflammation3 and
ocular surface damage.

The filaments are gelatinous structures, refractile
in appearance, consisting of a focal “head” firmly
adherent to the compromised areas of corneal
epithelium and a freely floating “tail” of varying
length4. The head is made up of a central core of
desquamated corneal epithelial cells, surrounded by
degenerating conjunctival epithelial cells and a thick
layer of mucin. They vary in size from 0.5 mm sessile
adhesions to 10 mm long strings. With each blink,
vertical friction causes a lot of ocular discomfort and
pain5, while further shearing of the corneal epithelium
results in increased inflammation of the underlying
exposed stroma. Mechanical removal of filaments
increases the inflammation and promotes further
filament formation. To manage filamentary keratitis6,
the treatment needs to be targeted towards treating
the underlying cause, the associated ocular surface

inflammation and preventing further epithelial
degradation, to remove/treat the filaments.

In order to address all these issues, the therapeutic
drug armamentarium must include topical lubricants
(to reduce the mechanical stress and ocular discomfort
by diluting inflammatory cytokines, and also stabilise
the tear film) and topical anti-inflammatory drugs
(tacrolimus, cyclosporin A, corticosteroids and non-
steroidal agents). In order to dissolve the filaments,
oral (Acetylcysteine, carboxymethyl cysteine,
bromhexine) as well as topical mucolytic agents like 5-
10% Acetylcysteine eye drops have been used in
various studies. They dissolve the filaments efficiently
but the main problem with these eye drops is the
severe ocular irritation, burning and stinging upon
their instillation that persists for 10-30 min. This
results in a reduced patient compliance to therapy.
Unless the filaments are dissolved efficiently, the
vicious cycle of further filament formation cannot be
broken. In Pakistan, commercially preparation of
Acetylcysteine eye drops are not available. With the
help of a dispensing pharmacist, we prepared a
diluted preparation of 0.3% Acetylcysteine eye drops
for our patients. This study was conducted to analyzse
whether such a diluted preparation can efficiently
dissolve the filaments and whether it is better
tolerated than the 5-10% preparation by the patients.

MATERIAL & METHODS

A prospective interventional study was conducted at a
tertiary care centre, for a period of two and a half
years, from April 2016–October 2018. An approval
from the centre’s ethical committee was obtained and
there was no conflict of interest to conduct this study.
During this period, 52 consecutive cases (104 eyes)
which presented with mild to severe filamentary
keratitis were included in the study. They were
between the age of 9-72 years (median 49 ± 8.6), with
31 females and 21 males. A detailed history was taken
regarding the duration and severity of symptoms,
systemic illness (arthritis, thyroid dysfunction,
psoriasis, vitiligo and other auto-immune disorders),
recent ocular surgery and a detailed list of all topical
and systemic medications being used by the patient.
The time spent on digital screens per day, occupation
and smoking was also noted. The baseline
characteristics of the 52 cases are shown in Table 1.
Cases with an active ocular surface infection, uveitis
and recent ocular surgery (< one month) and
pregnant/lactating patients were excluded from the
study.

SAMEERA IRFAN

265 Vol. 35, No. No. 4, Oct – Dec, 2019 Pak J Ophthalmol

A detailed ophthalmic
examination was performed
in order to assess the
underlying cause of the
patient’s problems and to
grade the severity of disease
before initiating the specific
therapy. Facial appearance
regarding brow droop,
increased frequency of
blinking, blepharospasm,
dermatochalasis, position
and contour of the eyelids
was noted. Presence or
absence of meibomian

Table 1: Baseline characteristics of 52 cases.

Age Range: 9 – 7 Years
Mean : 41.20
Median: 55

Sex Males: 21 (40.38%) Females 31 (59.61%)

Severity of Dry eyes Moderate: 16 cases (30.76%) Severe 36 cases (69.23%)

Severity of Filaments Mild: 4 cases (7.7%)
Moderate: 12 cases (23%)

Severe 36 cases (69.23%)

Underlying Cause Post-cataract Surgery: 4 cases
VKC : 6 cases
Facial palsy: 4 cases
Thyroid eye disease; 4 cases

Non-SS dry eyes: 23 cases
SS dry eyes: 5 cases
Stevens Johnsons: 8 cases

gland dysfunction was assessed by looking for lid
margin thickening, telangiectasia, hyperemia,
keratinization or frothing at the angles; noting the
quality of meibum, the ease with which it could be
expressed, position of the meibomian duct orifices,
their clogging or notching (indicating absence),
trichiasis/distichiasis.

The lower tear meniscus height and its clarity was
noted; the presence of corneal filaments, their
number/site, as well as that of corneal epithelial
punctate staining with fluorescein, corneal epithelial
defect, scarring, pannus formation was also noted.

The primary parameters assessed for the purpose
of the study were OSDI, fluorescein staining score
(FSS) of the ocular surface, TFBUT, and Schirmer’s 1
test. The patients were asked to fill in the Ocular
Surface Disease Index questionnaire7, OSDI, which is a
12-question survey that was developed by the
Outcomes Research Group at Allergan Inc;

To record the FSS8, the ocular surface was divided
into three zones: the nasal bulbar conjunctiva,
temporal bulbar conjunctiva, and the cornea. Each
zone was evaluated on a scale of 0-3, with 0 = no
staining, 1 = a few separated spots, 2 = many
separated spots, 3 = an area of confluent staining; the
maximum score possible was 9. The severity of
filamentary keratitis was graded by counting the
number of filaments on the cornea as grade 1 (mild) =
1-4 filaments, grade 2 (moderate) = 5-9 filaments,
grade 3 (severe) = filaments scattered over the whole
surface of cornea.

The Schirmer’s test readings were recorded after
instillation of one drop of topical anaesthetic (0.5%
proparacaine hydrochloride). In a silent room, away
from the fan, a filter paper strip (35 × 5 mm, bent at 5

mm) was placed at the lateral one-third of the lower
lid margin. Care was taken to prevent the paper from
touching the cornea, by asking the patient to look up
while placing the strip. The patient was instructed to
keep the eyes closed, and not to talk during the test.
After 5 minutes, the strip was removed and the level
of strip wetting (in mm) was measured. The tear
secretion was considered abnormal if the reading was
equal to or less than 15 mm.

All cases were prescribed the regular dry eyes
treatment protocol9 comprising of lubricant eye drops
1 – 2 hourly during the day (depending upon the
disease severity), lubricant eye ointment (lacrilube,
Allergan pharma) at night, anti-inflammatory therapy
as Tacrolimus skin cream 0.03% (Crolimus, Valor
Pharma) applied in the evening into the lower
conjunctival fornix by a cotton-tip. For the associated
meibomian gland dysfunction, tetracycline eye
ointment (Xinoxy, Remington pharma) was
prescribed, to be massaged into the lid margins at
night and application of a hot, wet towel to lid
margins for 10 minutes in the morning followed by
gentle scrubbing of closed eyelids with baby shampoo.
All patients were instructed to quit/reduce smoking
and drink at least 8 glasses of water daily.

In addition, the compounding pharmacist was
instructed to divide the alternate cases into two equal
groups; the odd number of cases, from 1-51 were
included in Group A, and even number of cases from
2-52 were included in the Group B, so that each group
consisted of 26 alternate cases. The Group A cases
received Acetylcysteine eye drops 0.3%, freshly
prepared by the compounding pharmacist, to be
instilled four times daily, whilst the Group B cases
received placebo eye drops (distilled water in a bottle).
Patients were instructed to keep the bottle refrigerated

THE EFFICACY & SAFETY OF 0.3% ACETYLCYSTEINE EYE DROPS IN FILAMENTARY KERATITIS

Pak J Ophthalmol Vol. 35, No. 4, Oct – Dec, 2019 266

in between instillation, discard them after a month and
get a fresh bottle from the pharmacist. Only the
compounding pharmacist had the list of cases who
received either the Acetylcysteine or the placebo eye
drops. The list was disclosed to the examining
ophthalmologist at the end of the study for analyzing
the results. The manual removal of filaments or
application of a bandage contact lens was not
performed in any case.

The severity of clinical symptoms (OSDI), the
number of corneal filaments, corneal fluorescein
staining, Tear Film BUT, Schirmer’s test readings were
recorded at baseline and then at each follow-up visit
which was conducted every 2 weeks for 12 weeks. For
statistical analysis, the SPSS software version 20 was
used. The data was expressed as mean and standard
deviation (frequency distributions ± SD) for the OSDI
score while it was expressed as median and range for
the FSS, TFBUT, Filament grade and Schirmer’s test. A
“paired" t-test was used to assess the scores from the
same set of patients (for both group A and Group B
cases) at baseline and then at the 12 week follow-up.
The final 12 week score obtained by Group A and B
cases was analyzed separately to see which indices
improved significantly between the two groups, and
p < 0.05 was taken to indicate statistical significant.
The efficacy analysis population included all cases that
completed the study. The safety analysis population
included all cases that were enrolled in the study. The
statistical analyses included data for the worst affected
eye.

RESULTS

The baseline demographics of the 52 consecutive cases
(104 eyes) included in the study are demonstrated in
Table1; there were 21 males (48.38%) and 31 females
(59.61%), with an age range of 9 - 72 years (mean 41.20,
and median 55 years).

Severe dry eyes were noted in 36 cases (69.23%)out
of the total 52 and were due to non-Sjogren’s
syndrome (SS) (23 cases) or SS (5 cases), and the
filaments were present in the inter-palpebral region of
the cornea along with punctate corneal staining in the
same region. The 8 cases due to chronic Stevens
Johnson’s syndrome also had severe dry eyes, with the
corneal filaments and staining diffusely scattered all
over the cornea. The remaining 16 cases (30.76%) had
dry eyes of a moderate severity. They included 6 cases
with acute-on chronic VKC, the filaments were present
next to the area of limbitis, while the 4 cases with
exposure keratopathy due to chronic facial palsy and 2

cases of thyroid eye disease had filaments at the lower
limbus. The 4 post-cataract surgery cases had a mild
dry eye with a few filaments at the incision site while
one had mucous plaques around the corneal sutures.

The presenting complaints of all 52 cases are
shown in Table 2; the most common presenting
complaints were ocular discomfort, photophobia and a
foreign body sensation in the eyes in all 52 cases
(100%). Corneal filaments were present in all 52 cases
(100%); the site of filaments was determined by the
underlying cause while the number was related to the
severity and chronicity of the disease.

Table 2: Frequency of symptoms in 52 cases.

Symptoms Baseline

Photophobia
Foreign body sensation
Eye pain
Eye discomfort
Itching
Blurred vision
Blepharospasm
Watering
Discharge

52 cases (100%)
52 cases (100%)
52 cases (100%)
52 cases (100%)
47 cases (90.38%)
31 cases (59.6%)
28 cases (53.84%)
47 cases (90.38%)
12 cases (23%)

The primary parameters assessed for the purpose
of the study are demonstrated in Table 3, and their
response to therapy in both groups from baseline till
12 weeks of regular two weekly follow-up. In all
group A cases, the OSDI score gradually improved
from a mean score of 41.5 ± 5.26 to 4 ± 1.5 over the 12
weeks of continued therapy with Acetylcysteine. Even
the diluted preparation of 0.3% efficiently removed
corneal filaments in all cases within 2-4 weeks of
therapy. A recurrence of filaments was noted only in 3
cases who had stopped using Acetylcysteine abruptly.
Therefore, the remaining patients were instructed to
continue with Acetylcysteine therapy for at least one
more month after the total clearance of filaments. All
26 cases in group A completed the 12 weeks follow-up
and showed excellent compliance to therapy. Only 2
patients (7.7%) complained of mild discomfort on
instillation of Acetylcysteine drops, but no pain or
stinging.

The fluorescein staining score (FSS), as shown in
Table 3, improved in group A cases from a median of
2 (range 1 – 4) at baseline, to 0 at 12 weeks follow up
which was highly statistically significant (p < 0.00001).
The TFBUT increased from 4 (range 1-7) sec to 9 (range
7-13) sec at 12 weeks, indicating a marked
improvement (p < 0.0001). The Schemer’s 1 readings

SAMEERA IRFAN

267 Vol. 35, No. No. 4, Oct – Dec, 2019 Pak J Ophthalmol

gradually improved in all cases from 2.5 (range 0-4)
mm at baseline to 8 (range 5-12) sec (p < 0.001), though
very slowly in cases with Stevens Johnson’s syndrome.

In group B cases, the OSDI score improved very
slowly and gradually from the baseline score of 40.67
to 28.5 ± 3.4 over the 8-10 weeks, despite the continued
use of lubricants and tacrolimus therapy. This was
much less improvement as compared to the group A
cases (improved to 4 ± 1.5). It was due to the
persistence of corneal filaments and the resultant

ocular discomfort, because of which 3 cases did not
complete the 12 weeks follow up and dropped out of
the study. A statistically significant difference (p =
0.05) between Acetylcysteine therapy and the placebo
group was found for the OSDI score as well as all the
objective parameters assessed i.e. the FSS, TFBUT and
Schirmer’s score, which showed only a slight
improvement in the placebo group, as demonstrated
in Table 3.

Table 3: Results: Comparison between group A & B.

Parameter Group Baseline 2 wks 4 wks 6 wks 8 wks 10 wks 12 wks p value

OSDI
A 41.5± 5.26 32 ± 6.97 24.5 ± 5.50 18 ± 3.26 11 ± 4.50 7 ± 4.60 4 ± 1.5 0.00001

B 40.67 37 ± 3.42 33 ± 5.55 31.5 ± 5.15 30.20 ± 4.42 28.5 ± 4.52 25 ± 3.4 0.01

Filament
grade

A 3 (1-3) 2 (1-3) 0.5 (0-1) 0 0 0 0 0.00001

B 3 (1-3) 3 (1-3) 2 (1-3) 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2) > 0.5

FSS Score
A 2 (1-4) 2 (1-3) 1 (1-2) 1 (0-1) 0 (0-1) 0 0 <0.00001

B 2 (1-4) 2 (1-3) 2 (1-3) 2 (1-2) 1 (0.5-2) 1 (0-1.5) 0 (0-1) <0.5

TFBUT
sec

A 4 (1-7) 4 (3-7) 5 (4-8) 7 (4-9) 8 (5-11) 8.5 (5-13) 9 (7-13) < 0.0001

B 4 (1-6) 4 (1-7) 4 (2-8) 5 (3-7) 5 (3-8) 5.5 (4-9) 6 (5-9) < 0.01

Schirmer
Test mm

A 2.5 (0-4) 3 (1-4) 4 (2-5) 5 (4-7) 6 (4-8) 7 (5-9) 8 (5-12) < 0.001

B 2 (0-4) 2 (0-4) 3 (1-5) 3 (1-6) 4 (2-6) 4 (3-6) 5 (3-7) < 0.01

FSS (Fluorescein Staining Score), TFBUT (Tear-film Break up Time), Schirmer’s test readings: shown as median
and range (minimum to maximum).

DISCUSSION

Filamentary keratitis is a sight-threatening and a
functionally debilitating complication of a number of
ocular and systemic conditions, as already mentioned.
The site of filament formation depends upon the
underlying cause. In our study, the cases with aqueous
deficient dry eyes (SS and non-SS = 5 + 23 = 28 cases)
and exposure keratopathy due to facial palsy (4 cases)
and proptosis due to thyroid eye disease (4 cases), the
filaments were noted in the inter-palpebral area. This
was due to an excessive evaporation of aqueous from
the most exposed area of the ocular surface. The
additional factors noted in these patients were
smoking, working in an indoor environment, air
pollution, prolonged staring at digital screens
(computers, mobile phones10, television) or prolonged
reading which reduces the blinking rate and
replenishing the tear film.

The 4 post-cataract surgery cases in our study
complained of watery eyes, intermittent blurring of
vision and grittiness that gradually worsened over 2-6
months after the surgery, which was performed in
both eyes one after the other. Corneal filaments were
noted at the site of corneal incision in 3 cases and
around the corneal sutures in one case. This was due
to a pre-existing mild to moderate tear film instability
that generally exists in the elderly population due to
androgen deficiency and was missed pre-operatively.
The added surgical trauma11,12 destroyed the nerve
plexus at the incision site and reduced the corneal
sensitivity and the TFBUT. Moreover, the mechanical
injury from surgical instrumentation, chemical toxicity
of medicines (particularly the preservatives) used pre-
operatively, intra-operatively and during the post-
operative period, and the co-existent meibomian gland
dysfunction in this age group, further aggravated the

THE EFFICACY & SAFETY OF 0.3% ACETYLCYSTEINE EYE DROPS IN FILAMENTARY KERATITIS

Pak J Ophthalmol Vol. 35, No. 4, Oct – Dec, 2019 268

ocular surface inflammation mainly at the site of
corneal incision/suture (due to suture irritation) and
filaments formed in the late postoperative period at
that site. It takes a long time for the composition and
production of the tear film to recover post-operatively.
However, all our cases responded well to the dry eyes
therapy and the 0.3% Acetylcysteine eye drops; their
vision cleared up as well as the ocular discomfort.

In VKC (6 cases) and autoimmune disorders
(Sjogren’s syndrome 5 cases), the filaments were noted
at the limbal area. This is because the corneal limbal
tissue is vulnerable to inflammatory mediators,
antibodies, and complement released by the activated
eosinophils and lymphocytes present in the peri-
limbal vascular arcade13. The perilimbal swelling
results in tear-film instability and filaments are formed
in that area. Additionally, the autoimmune disease
process often affects the secretion of lacrimal gland,
conjunctival goblet cells, and meibomian glands
resulting in a severe form of dry eyes. Ultimately, the
filaments are distributed over the whole cornea.
According to various studies, allergic conjunctivitishas
been found to be accompanied by dry eyes with an
incidence of 62.5% to 83.3% while itching of eyes have
frequently been noted as a symptom of dry eyes.

Systemic medications14 like diuretics, anti-
histaminics and anti-depressants reduce the
production of aqueous and can alter the balance
between aqueous: mucin in the tear film, thereby
precipitating filamentary keratitis. One patient in our
study with VKC was on oral anti-histaminic and two
were on diuretics. When these were stopped, their
OSDI improved rapidly.

In this study, 38 cases were already on topical
lubricants for months and they still developed the
corneal filaments. Therefore, the addition of anti-
inflammatory medicines topically was mandatory.
Tacrolimus15,16 has been used in various studies as a
potent anti-inflammatory agent when applied
topically as 0.03% eye drops. Similar to cyclosporin
eye drops 17, it is a potent calcineurin inhibitor, known
to reduce the ocular surface inflammation by
inhibiting the T cell-mediated immune responses.
They both promote corneal healing and improve
secretion and quality of all the three components of
the tear-film. They are safe drugs with minimal side
effects (stinging and burning upon instillation) after
prolonged usage, in comparison to the topical steroids
that can be safely used for dry eyes for only 1-2 weeks.
Since the tacrolimus eye drops are not available
commercially, the 0.03% skin cream (Crolimus by

Valor pharma) was prescribed to all cases, to be
applied into the lower conjunctival fornix twice daily.

Patients with associated meibomitis18 were
advised warm wet towel application to closed eyelids
twice daily; the heat melts the thick meibum and
opens up the clogged duct orifices. They were also
instructed to scrub the lid margin with baby shampoo,
after the hot fomentation, so as to remove the melted
toxic meibum and massage tetracycline eye ointment
into the lid margins at night to control the associated
inflammation of the meibomian glands and the
eyelids. For the severe cases of MGD, oral tetracyclines
(Doxycycline 100 mg/day for 6 weeks) were also
prescribed. In patients with severe ocular pain or
discomfort, topical diclofenac sodium 0.1% eye drops
three times a day was added to the therapeutic
armamentarium; this not only reduces the ocular
discomfort but has an additive anti-inflammatory
affect.

Filaments on the ocular surface can be dissolved
by using topical or oral mucolytic agent like N-
Acetylcysteine19 which is a derivative of the natural
amino acid L-cysteine. It is frequently used in acute
and chronic broncho-pulmonary disease. It exerts its
affects by opening up the disulfide bonds in
mucoproteins, thereby lowering the viscosity of
mucous, inhibiting collagenase enzymes that are
secreted by inflammatory cells and cause corneal
thinning by melting collagen, by chelating calcium or
zinc, it inhibits MMP-9 secretion, thereby inhibiting
the inflammatory cytokine responses and reducing
ocular surface inflammation.

Hence, Acetylcysteine has multiple beneficial
effects in filamentary keratitis. It is available in Europe
and USA commercially. A recent preparation,
Chitosan-N-Acetylcysteine20 has been used in various
studies with remarkable results in dry eyes associated
with filamentary keratitis. Unfortunately, no
commercially prepared eye drops are available locally
in the market, and it has to be prepared on request by
a compounding pharmacist. It is readily available as
tablets and in sachets containing powder (Mucolyte
200 mg) that is water soluble. It is a relatively strong
acid and cannot be applied directly to the ocular
surface, but only after being suitably neutralised. The
prepared solution should have a neutral pH between
6.6-7.5. The solvent used for preparing the solution
and neutralisation should not increase the osmolarity
from an initial value of 241 mOsm/kg (of the
powdered form) to more than 300 mOsm/kg. The 5%
or 10% N-Acetylcysteine solution that has been used

SAMEERA IRFAN

269 Vol. 35, No. No. 4, Oct – Dec, 2019 Pak J Ophthalmol

in various studies had a much higher osmolarity of >
1000 mOsm/kg. We previously used 0.5% preparation
but that also caused a lot of stinging in the eyes upon
instillation. It is due to the high osmolarity of these
preparations which irritates the inflamed, irritable
ocular surface. The 5% eye drops cause a lot of ocular
surface irritation (manifested as stinging, burning on
instillation of eye drops and an increase in punctate
epithelial erosions) and potential corneal damage as
the tear fluid is already hypertonic in patients with the
dry eyes syndrome.

In this study, we used a diluted preparation of
0.3% Acetylcysteine eye drops, freshly prepared by
our compounding pharmacist. The pH was kept at 7
and osmolarity of the prepared solution at 300
mosmol/litre. The patients were instructed to keep the
freshly prepared eye drops refrigerated at 2-8ºC. to
avoid decomposition of the solution. It not only
dissolved the corneal filaments efficiently within 2-4
weeks in all group A cases but helped in restoring the
quality of mucin, so that further formation of filaments
was not noted in cases that continued using it for at
least 6-8 weeks even after the filaments had cleared
up. Recurrence was noted in only 3 cases who
abruptly stopped Acetylcysteine. It also helped in
improving the overall OSDI score, the tear-film BUT
and corneal staining in all group A cases. This was
because the diluted preparation was well tolerated
with no ocular discomfort or stinging, thus ensuring a
good patient compliance. The marked improvement in
patient’s symptoms and clinical signs was particularly
noticeable early within 2-4 weeks in cases with VKC,
post-cataract surgery and exposure keratopathy due to
facial palsy and Thyroid eye disease.

This was in comparison to the 26 group B cases in
which despite the usual treatment protocol for dry
eyes, the absence of a mucolytic agent delayed the
clearance and further production of filaments. The
filamentary keratitis persisted for 8-10 weeks despite
using lubricants, Tacrolimus and tetracycline eye
ointment so the ocular discomfort failed to show a
remarkable improvement. The other parameters
assessed also failed to show as much improvement as
in Group A cases. There was no possible bias in the
study as the lead ophthalmologist conducting the
study was totally unaware as to which cases were
using 0.3% Acetylcysteine eye drops or placebo.

Manual debridement of filaments can be
performed under topical anaesthesia, using a fine-
tipped forceps at the slit lamp. But it was not done in
any case in our study as pulling upon the corneal

filaments causes traction on the corneal epithelial cells,
resulting in more damage to the underlying
epithelium with shearing of their basal lamina; this
increases the ocular surface inflammation (by the
release of cytokines from the damaged epithelial cells)
and further promotes the adherence of mucus as well
as recurrent filament formation.

CONCLUSION

Filamentary keratitis is a chronic, recurrent, and
debilitating condition. With the correct and a
systematic approach to diagnosis and management,
the acute condition can be effectively controlled and
the incidence and severity of recurrences minimised.
Certain important points highlighted by this study
need to be kept in mind while managing such patients:

1) Acetylcysteine eye drops constitute an integral
part of the therapy of filamentary keratitis due to
any cause. 0.3% Acetylcysteine eye drops
efficiently clear up the filaments and are well
tolerated by the patients, thus ensuring a better
compliance to therapy. Manual removal of corneal
filaments should be avoided.

2) The therapy has to be continued for at least 6
weeks even after the filaments have cleared up, to
avoid recurrence.

3) Filamentary keratitis can be induced or
exacerbated by systemic medications and ocular
surgery, particularly in the elderly age group.
Therefore, a pre-operative assessment for dry eyes
should be considered in the surgical planning of
such patients by tear film break up time and
Schirmer’s test.

REFERENCES

1. Mannis MJ, Holland EJ, Gensheimer WG, Davidson
RS. Chapter 85: Filamentary Keratitis. In: Cornea:
Fundamentals, Diagnosis and Management. Vol 1. 4th
ed. Elsevier, 2017: 1025-1029.

2. Bron AJ, de Paiva CS, Chauhan SK, Bonini S, Gabison
EE, Jain S, Knop E, Markoulli M, Ogawa Y, Perez V,

Uchino Y, Yokoi N, Zoukhri D, Sullivan DA. TFOS
DEWS II Pathophysiology Report. Ocul Surf. 2017 Jul;
15 (3): 438-510.

3. Nelson JD, Craig JP, Akpek ET, Azar DT, Belmonte C,
Bron AJ, et al. TFOS DEWS II. Introduction. Ocul Surf.
2017; 15: 269-5.

4. Tanioka H, Yokoi N, Komuro A, Shimamoto T,
Kawasaki S, Matsuda A, Kinoshitaet S, et al.
Investigation of the corneal filament in filamentary
keratitis. Invest Ophthalmol Vis Sci. 2009; 50: 3696-3702.

https://www.ncbi.nlm.nih.gov/pubmed/?term=Azar%20DT%5BAuthor%5D&cauthor=true&cauthor_uid=28736334
https://www.ncbi.nlm.nih.gov/pubmed/?term=Belmonte%20C%5BAuthor%5D&cauthor=true&cauthor_uid=28736334
https://www.ncbi.nlm.nih.gov/pubmed/?term=Bron%20AJ%5BAuthor%5D&cauthor=true&cauthor_uid=28736334

THE EFFICACY & SAFETY OF 0.3% ACETYLCYSTEINE EYE DROPS IN FILAMENTARY KERATITIS

Pak J Ophthalmol Vol. 35, No. 4, Oct – Dec, 2019 270

5. Galor A, Batawi H, Felix ER, Margolis TP,
Sarantopoulos KD, Martin ER, Levitt RC. Incomplete
response to artificial tears is associated with features of
neuropathic ocular pain.Br J Ophthalmol. 2016 Jun; 100
(6): 745-9.

6. Mridula Pentapati, Suchi Shah. Filamentary Keratitis.
A Case Series. International Journal of Scientific and
Research Publications, Volume 5, Issue 3, March 2015. 1
ISSN 2250-3153.

7. Grubbs JR, Tolleson-Rinehart S, Huynh K, Davis RM.
A Review of Quality of Life Measures in Dry Eye
Questionnaires. Cornea, 2014; 33 (2): 215-218.

8. J. Bron, P. Argüeso, M. Irkec, and F. V. Bright, “Clinical
staining of the ocular surface: mechanisms and
interpretations,”Progress in Retinal and eye Research,
2015; Vol. 44: pp. 36–61.

9. Sambursky R. Presence or absence of ocular surface
inflammation directs clinical and therapeutic
management of dry eye. Clin Ophthalmol, 2016; 10:
2337-43.

10. Moon JH, Kim KW, Moon NJ. Smartphone use is a risk
factor for pediatric dry eye disease according to region
and age: a case control study. BMC Ophthalmol. 2016
Oct 28; 16 (1): 188.

11. Denoyer A, Landman E, Trinh L. Dry eye disease after
refractive surgery: comparative outcomes of small
incision lenticule extraction versus LASIK.
Ophthalmology, 2015; 122: 669–676.

12. Cho YK, Kim MS. Dry eye after cataract surgery and
associated intraoperative risk factors. Korean J
Ophthalmol. 2009 Jun; 23 (2): 65-73.

13. Chen L, Pi L, Fang J, Chen X, Ke N, Liu Q. High
incidence of dry eye in young children with allergic
conjunctivitis in Southwest China. Acta Ophthalmol.
2016 Dec; 94 (8): e727-e730.

14. Lyndon Jones, Laura E. Downie, Donald Korb, Jose
M. Benitez-del-Castillo, Reza Dana, Sophie X. Deng,
Pham N. Dong et al. TFOS DEWS II Management and
Therapy Report, The Ocular Surface, 2017; 15: 575-628.

15. Moscovici BK, Holzchuh R, Sakassegawa-Naves FE,
et al. Treatment of Sjogren’s syndrome dry eye using
0.03% tacrolimus eye drop: Prospective double-blind
randomized study. Cont Lens Anterior Eye, 2015 May 5.

16. Samir S. Shoughy Topical tacrolimus in anterior
segment inflammatory disorders. Eye and Vision, 2017;
Volume 4, Article Number 7.

17. Irfan S and Qurban T. Ophthalmic uses of cyclosporine
eye drops. F1000Research 2016, 5: 1941 (poster).

(DOI: 10.7490/f1000research.1112798.1)
18. Irfan S. Meibomian Gland Dysfunction.Review Paper.

PJO, Jan-March 2019; Volume 35, Issue No 1.
19. Ramaesh T, Ramaesh K, Riley SC, West JD, Dhillon B.

Effects of N-Acetylcysteine on matrix
metalloproteinase-9 secretion and cell migration of
human corneal epithelial cells. Eye (Lond). 2012; 26 (8):
1138-44.

20. Lorenz K, Garhofer G, Hoeller S, Peterson W,
Vielnascher RM, Ivezi Z. Long-term management of
dry eye by once-daily use of Chitosan-N Acetylcysteine
(Lacrimera®) eye drops. J Clin Ophthalmol.2018; 2 (1).

DOI: 10.35841/clinical- ophthalmology.2.1.47-54e.

Author’s Affiliation

Dr. Sameera Irfan
FRCS
Consultant

Author’s Contribution

Dr. Sameera Irfan
Literature review, Manuscript writing.

https://www.ncbi.nlm.nih.gov/pubmed/27788672
https://www.ncbi.nlm.nih.gov/pubmed/27788672
https://www.ncbi.nlm.nih.gov/pubmed/27788672
https://www.ncbi.nlm.nih.gov/pubmed/27226346
https://www.ncbi.nlm.nih.gov/pubmed/27226346
https://www.ncbi.nlm.nih.gov/pubmed/27226346
http://dx.doi.org/10.7490/f1000research.1112798.1
https://doi.org/10.35841/clinical-ophthalmology.2.1.47-54