Iraqi J Pharm Sci, Vol.30(2) 2021         Study of microbial contamination of some commercial contact lenses' solutions                                                

DOI:  https://doi.org/10.31351/vol30iss2pp214-218 

214 

 

Study of Microbial Contamination of Some Commercial Contact Lens 

Solutions 
Faris Ali Muhammed Al-Hilli *,1 

 
* Department of Clinical Laboratory Sciences, College of Pharmacy, University of Baghdad, Baghdad. Iraq. 
Abstract 

Microbial contamination is very common among contact lens users whether contamination involves the 

solutions or the lens. Many bacteria cause eye infections through this route and some may lead to serious outcomes 

to the eye. Most isolated bacteria from previous studies on the subject belong to Gram negative bacteria and few 

Gram positive bacteria. Our study was aimed at identifying microbial contamination of contact lens solutions from 

students at the College of Pharmacy/ University of Baghdad. The lenses used were varied from medical to 

cosmetic types. Both used and unused solutions were subjected for culturing to diagnose any microbial 

contamination. Thirty six (60%) of used samples showed bacterial growth. Pseudomonas aeruginosa accounts for 

the highest number of isolates (25%) followed by E. coli (21%), Staphylococcus epidermidis (6.6%), 

Pseudomonas fluorescence (5%) and Proteus mirabilis (1.6%) respectively. Only one unused (sealed) sample 

showed growth of P. fluorescence. Fungal growth was absent in both used and unused lenses. The bacterial 

contamination is likely  to come from bad personal hygiene and improper or misuse of the solutions where these 

bacteria especially P. aeruginosa are frequently found in various environments from skin to solid materials and 

surfaces and are known to thrive in harsh environments. No relation was found between eye associated diseases 

and solution contamination among contact lens users. Special care should be paid in maintaining aseptic solutions 

and proper handling to avoid transmitting harmful bacteria to the eye where it may lead to serious eye infections. 
Keywords: Contact lens solution, Microbial contamination, Eye infections, Pseudomonas aeruginosa, Staphylococcus 

epidermidis 

 سات الالصقة التجاريةدراسة التلوث المايكروبي لبعض محاليل العد
 1*،فارس علي محمد الحلي

 العراق .، ، بغداد جامعة بغداد، كلية الصيدلة ،  فرع العلوم المختبرية السريرية *

 الخالصة
يعتبر التلوث الميكروبي من االمور الشائعة عند مستخدمي العدسات الالصقة بغض النظر اذا كان التلوث يحدث في المحاليل الخاصة ام 

للعين. العدسات نفسها. يوجد العديد من البكتريا التي تسبب عدوى للعين عن طريق هذا المسلك من االصابه و قسم منها قد تؤدي الى عواقب خطيرة 

ام.تهدف اشارت الدراسات السابقة في هذا المجال الى ان اكثر البكتريا المعزوله هي سالبة لصبغة كرام و القليل من المجاميع الموجبة لصبغة كر

ن عينة من محاليل العدسات وتم جمع ستالدراسة الى تشخيص التلوث الميكروبي لمحاليل العدسات الالصقه بين طالب كلية الصيدلة في جامعة بغداد.

 أوساط في وضعهام ت. تتنوع أنواع العدسات المستخدمة من الطبية إلى التجميلية. جامعة بغداد /الالصقة المتوفرة تجارياً من طالب كلية الصيدلة 

أظهرت ست . زرع المايكروبيخاضعة لل (الجديدة)المستعملة وغير  المستعملة المحاليلكانت . لتشخيص أي تلوث ميكروبي داخل المحاليل زرعية

أكبر عدد من العزالت  Pseudomonas aeruginosaتمثل . فطري نمو أي يظهر ولمنمًوا بكتيريًا ،  المستعملةمن العينات ( 60%)وثالثون 

 Proteus% )و E. coli (21،%( ,Staphylococcus epidermidis (6.6 Pseudomonas fluorescence (5%)% )تليها( 25%)

mirabilis (1.6 نمو ( جديدة) مستعملةأظهرت عينة واحدة غير . على التواليPseudomonas fluorescence . من المحتمل أن يكون هذا التلوث

في بيئات مختلفة من الجلد  P. aeruginosaحيث توجد هذه البكتيريا وخاصة  المحاليل مالبكتيري ناتًجا عن النظافة الشخصية السيئة وسوء استخدا

وث المحلول لم يتم العثور على عالقة بين األمراض المرتبطة بالعين وتل. إلى المواد الصلبة واألسطح ومن المعروف أنها تزدهر في البيئات القاسية

يجب إيالء عناية خاصة في الحفاظ على المحاليل المعقمة والتعامل المناسب لتجنب انتقال البكتيريا الضارة إلى . مستخدمي العدسات الالصقة ضمن

 .العين حيث قد تؤدي إلى التهابات خطيرة للعين
 Pseudomonas aeruginosa ،Staphylococcus epidermidisالعين، الكلمات المفتاحية:  محلول العدسات الالصقة، التلوث المايكروبي، اصابات 

 

Introduction 
Contact lenses are thin plastic lens worn 

between the eye and eyelid that may be used instead 

of eyeglasses. Actors, models, and others wear them 

for appearance, and athletes use them for safety and 

convenience. Contact lenses may also be used to 

correct certain abnormalities of the eye that cannot 

be corrected by regular glasses. It was invented in 

1887 but was not used until 1938 when the first 

plastic contact lens was introduced. In 1950, the  

 

 

corneal contact lens was introduced. It covered only 

the cornea of the eye, floated on the tears of the 

wearer, and could be worn all day without difficulty. 

Recent improvements include flexible lenses that 

shorten the initial period of adjustment for the 

wearer and porous lenses that do not have to be 

removed each day. Today, contact lenses that 

"breathe" have become popular. They allow oxygen 

to get to the cornea, preventing blurred vision due to 

the corneal exhaustion Syndrome (1,2).  

  
1Corresponding author E-mail: scorpionc3po2000@gmail.com 
Received: 26/11/2020 

Accepted:20 /6 /2021 

Published Online First: 2021-12-11 

Iraqi Journal of Pharmaceutical Science  

https://doi.org/10.31351/vol30iss2pp214-218


Iraqi J Pharm Sci, Vol.30(2) 2021         Study of microbial contamination of some commercial contact lenses' solutions                                                

215 

 

The solutions that preserve contact lenses 

are subject to contamination by microorganisms 

such as bacteria and fungi and may lead to serious 

infections through the invasion of the cornea and 

conjunctiva(3).    

Staphylococcus aureus, Pseudomonas, 

Bacillus, Proteus,   Haemophilus,    Enterobacter,     

Serratia, and  Klebsiella spp. are the most common 

isolated bacteria from eye infections related to 

contaminated medications(4). These bacteria can 

damage important functional structures which might 

lead to vision loss and blindness (5). Bacterial 

keratitis and endophthalmitis are some of these 

serious infections that were found to be associated 

with the use of contaminated topical medications (6-

8). The contamination rate of in-use ophthalmic 

solutions is variable according to published 

researches and ranges from 0.07% to 35.8 %(9). Most 

eye preparations may possess antimicrobial effect 

and if not they are provided with antimicrobial 

substances to prevent contamination. These 

substances prevent microbial growth to avoid 

infection of the eye and drug degradation (10). In a 

study by Tsegawa et.al on 100 ophthalmic solutions 

used by patients and eye care workers cultured for 

microbial contamination, it was found that 11% 

were contaminated with various bacterial species 

and the significant findings of this study were the 

isolation of resistant Staphylococcus aureus and 

coagulase negative Staphylococcus both were 

methicillin resistant among other species(4). 

The current study focused on screening for 

microbial contamination in commercially eye lens 

solution used by students at College of Pharmacy/ 

University of Baghdad.  
 

Materials and  Methods 
Specimen collection  

The samples were collected from October 

2018 until May 2019. Sixty samples were collected 

form students at College of Pharmacy/University of 

Baghdad. 

Sample characteristic 

1- The samples were collected from 58 females and 
2 males. 

2- Fifty eight samples were extended wear, and 2 
samples were daily wear. 

3- Five samples have been used as medical lenses, 
while 55 samples have been used as cosmetic lenses. 

4- Associated eye disease: one sample has a previous 
history of Toxoplasmosis retinitis infection in the 

right eye. While the other samples have astigmatism 

as diagnosed by ophthalmologists.  

5- The manufacturing companies were the most 
common available in the Iraqi market and they were; 

BELLASOFT, NEOPLUS , FRESHEYE, SAFE & 

SOUND, HD, MY CHOICE, ANASTASIA, 

DESIO, CUTE, AQUASOFT, HEIDI , 

FRESHLOOK and they were manufactured mainly 

in Korea, Syria and France.  

6- The collected solutions were divided into two 
groups: 20 new and 40 used solutions for 

comparison and culturing. 
 

Culture media 

The samples were cultivated on nutrient 

agar, MacConkey agar, Mannitol salt agar and blood 

agar to isolate the bacteria. Sabaraud Dextrose agar 

was used to isolate the fungi. All media were 

sterilized in autoclave at 121⁰C for 15 min. prior for 

sub culturing. Duplicate cultures were made for each 

sample. 
 

Identification of microorganisms 
Nutrient agar was used to identify gram 

positive bacteria, while MacConkey agar was used 

to identify gram negative bacteria. Hydrogen 

peroxide solution (3%) was used to distinguish 

between Staphylococcus and Streptococcus. 

Mannitol salt agar was used to differentiate 

Staphylococcus aureus growth from Staphylococcus 

epidermidis. Gram negative bacteria were isolated 

by MacConkey agar, Oxidase test and growth at 

4⁰C/42⁰C(both were used to identify Pseudomonas 

species) and Triple Sugar Iron agar test also done for 

confirmation of the identification. The API 20E test 

system was used for the performance of 20 standard 

biochemical tests that differentiate various species 

of Enterobacteriace & other gram negative bacteria. 

(11). 

Results and Discussion 
Results 

Of the total 60 samples collected and 

cultured, all new 20 solutions (not used with contact 

lenses) showed negative growth except one sample 

showed growth of Pseudomonas fluorescence  while 

the used solutions showed that 36 out of 40samples 

were contaminated with bacteria. No fungal growth 

was observed in all samples. Table1shows the types 

of bacterial pathogens isolated from the samples 

with number and percentage of contamination 

analyzed through SPSS program.   

Table1. Microorganisms isolated from 
contaminated used  lens solutions samples 
 

Pathogen No. of 

samples 

% 

Pseudomonas 

aeruginosa 
15 41.6 

Escherichia coli 13 36.1 

Staphylococcus 

epidermidis 
4 11.1 

Pseudomonas 

fluorescence 
3 8.3 

Proteus mirabilis 1 2.7 

Total  36 samples 100 

 
 
 



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Discussion 
 Pseudomonas aeruginosa was the most 
frequent isolated bacteria from samples that 

included in this study. Contamination with 

Pseudomonas aeruginosa may be due to many 
reasons, as bad storage of the solution, long time of 

the solution storage without replacing it frequently, 

bad hygiene means, when the lens removed from the 

eye and inserted directly into the solution bags 

without rinsing or washing the lenses with the 

solution.  

Sometimes, the eye was infected before wearing the 

contact lenses. Contact lens with the persistence eye 

diseases may worse the condition (12). 

In the past, hard contact lenses were sterilized 

in boiling water. When they were replaced by soft 

lenses, boiling water sterilization was discarded due 

to the damage and deterioration that it causes to 

theses soft ones. Furthermore, this type of 

sterilization causes allergic diseases (13). Care system 

bottles can be easily contaminated and become a 

source of microbes that contaminate the lens storage 

cases (14,15). 

The results of the current study revealed that all new 

solutions showed no growth except one sample 

which was contaminated by Pseudomonas 

fluorescence. All types of care solutions, including 

hydrogen peroxide, have been reported to contain 

microorganisms even in experienced users or 

unopened factory sealed bottles (16,17). It may be 

possible that contamination occurred during 

packaging in the factory. No gram positive bacteria 

or fungus were found in the cleaning solutions.  

Gram negative bacteria have the best 

opportunity to contaminate lens care solutions due 

to their ability to adapt to various environments even 

with minimum nutritional requirements (18).  

The reason for such findings might be due 

to the fact that the moist tips of solutions might serve 

as a reservoir for microbial contamination, and this 

will put the risk of contaminating the eye drop with 

bacteria as a result of touching the dropper tips while 

opening it for usage, contact of dropper with the 

ocular tissues, and environmental factors(4). Lens 

care solutions are provided with preservatives and 

some disinfectants such as Alexidine 

Dihydrochloride, Polyhexamethylene Biguanide, 

Oxychlorite complex (sodium chlorite and hydrogen 

peroxide), benzalkonium chloride and other 

compounds. These are added to maintain low levels 

of microorganism during the product’s life cycle 

whilst having minimal impact on the ocular surface 

(19). Narayana et.al observed in their study that the 

antimicrobial activity of different solutions varies 

with respect to time of incubation, and also there was 

a marked difference in the activity of some solutions 

against some pathogens like Pseudomonas 

aeruginosa and Staphylococcus aureus and they  

 

 

 

concluded that the users should store their lenses in 

solutions for longer periods of time (20). The stock  

 

solutions are intended to prevent microbial growth 

due to their antimicrobial efficacy however, 

common pathogens of the eye such as 

Staphylococcus aureus and Pseudomonas 

aeruginosa are becoming increasingly resistant to 

some commercial solutions(12,21). 

Gram negative bacteria, especially 

Pseudomonas aeruginosa has the ability to form 

biofilms on various materials both living and non-

living surfaces and the biofilm formation is an 

obstacle concerning the uses and design of ocular 

devices, such as contact lenses because it shelters 

the bacteria from harmful factors like antibiotics and 

the immune system thus leading to infection of the 

eye (22). Oliver et.al mentioned in his study that 

biofilms of P. aeruginosa resist multipurpose 

contact lens solutions and cause contamination but 

ozonized water and chlorohexidine reduced biofilm 

formation by reduction in bacteria numbers with 

ozonized water much more preferable as it doesn’t 

depose any toxic residues like chlorohexidine (23). 

Escerichia coli are the 2nd most 

contaminant isolated in our study. It has been 

isolated from contact lens solutions from previous 

studies and cause a problem in daily wear lens 

users(24,25). As mentioned by Demirbilek and 

Evrenin their study on multipurpose contact lens 

solutions, 5% Povidon iodine was more effective in 

elimination of this bacteria (26).      

As for the single isolate of Pseudomonas 

fluorescence, this bacterium is common in soil and 

it is known to cause infections in 

immuncompromised persons such as cancer patients 

through blood transfusions and saline solutions 

contamination (27). It is likely that this bacterium 

contaminated the solution during the manufacturing 

and filling of the product within the factory limits as 

it was found in new contact lens solution sample 

(sealed). 

While Staphylococcus epidermidis is a 

common commensal inhabitant of the skin at various 

sites, this bacteria is now widely studied and under 

monitoring due to increasing nosocomial infections 

caused by it. Some authors call it "the accidental 

pathogen" where it infects immune-compromised 

hosts and introduced to the system via instrument 

like urethral catheters. There is also an increasing 

resistant among nosocomial infections with these 

bacteria (28). The isolation of this bacterium among 

contact lens solutions most likely came from hands 

or contaminated bottle tips from the environment 

where these bacteria are commonly found. Correa 

et.al mentioned that S. epidermidis was one of the 

isolated bacteria from silicone hydrogel contact lens 

if they were used incorrectly or maladapted and lead 

to eye infection. Also, this may lead to 



Iraqi J Pharm Sci, Vol.30(2) 2021         Study of microbial contamination of some commercial contact lenses' solutions                                                

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contamination of solutions if they were 

Bacteriocidally inefficient in eliminating them (29).  

Proteus mirabilis is well known as one of 

the most frequent causative agent of urinary tract 

infections as well as causing wound infection, sepsis 

and pneumonia in hospitalized patients (30). It also 

can contaminate any material due to its actively 

swarming movement on solid surfaces. Lipener et.al 

mentioned in his study that P. mirabilis  was the 

second most frequently isolated bacteria along with 

P. aeroginosa  from contact lens saline solutions 

with a percentage of 60% (31). It is likely that these 

bacteria contaminated the solutions via hands with 

poor hygiene or improper handling of the solutions. 

There were no relation between eye associated 

diseases and solution contamination as both healthy 

and disease associated eyes showed contamination 

of contact lens solutions by their users.  
 

Conclusion  
 Contact lens solutions users should pay 
more attention to restrictions and medical guidelines 

in maintaining aseptic solutions free from microbial 

contamination. Lens solution could be a source of 

eye infection if aseptic procedures were ignored. 

College students are likely to get contamination and 

infections due to the crowded environment where 

they study and that there are many sources and 

material that provide these microbes.  
 

Acknowledgement 
  The author would like to thank pharmacist 
Marwa Mohammed for her assistance in sample 

collection from students and also special thanks to 

college of Pharmacy/ University of Baghdad and 
especially, clinical laboratory sciences department 

for providing all the possible facilities to accomplish 

this research with good effort.    
 

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