Back to Journals » Clinical Optometry » Volume 13

Hydrogen Peroxide Disinfecting Solution for Gas Permeable Contact Lenses: A Review of the Antimicrobial Efficacy, Compatibility, and Safety Performance of a One-Step Lens Care System

Authors Gabriel MM, McAnally C , Chen H , Srinivasan S, Manoj V, Garofalo R

Received 2 September 2020

Accepted for publication 19 November 2020

Published 14 January 2021 Volume 2021:13 Pages 7—14

DOI https://doi.org/10.2147/OPTO.S280046

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Mr Simon Berry



Manal M Gabriel,1 Cynthia McAnally,2 Huagang Chen,2 Sruthi Srinivasan,1 Venkiteshwar Manoj,1 Renee Garofalo2

1Research and Development, Alcon Research, LLC, Johns Creek, GA, USA; 2Research and Development, Alcon Research, LLC, Fort Worth, TX, USA

Correspondence: Renee Garofalo Research and Development
Alcon Research, LLC, Fort Worth, TX, USA
Tel +1 817 751 9321
Email [email protected]

Abstract: CLEAR CARE PLUS (CCP), also known as AOSEPT PLUS with HydraGlyde, is approved for use with gas permeable (GP) lenses, and the indication is supported by the scientific evidence that is reviewed in this article. Antimicrobial efficacy testing of CCP both as a stand-alone disinfectant and as part of a regimen shows that CCP exceeds the ISO 14729 criteria against bacteria, yeast, and mold. In real-world conditions, it is effective against clinically relevant bacterial strains isolated from adverse events and against the two forms, trophozoites and cysts, of resilient Acanthamoeba species. Compatibility tests of CCP with two types of GP lenses indicate that the physical and/or optical parameters of lenses are unaffected through 30 cycles of simulated use with CCP, and a clinical trial shows substantial equivalence of clinical performance with a commonly used GP multipurpose solution. These results indicate that CCP is well suited for cleaning and disinfection of GP contact lenses.

Keywords: antimicrobial efficacy, CLEAR CARE PLUS, AOSEPT PLUS with HydraGlyde, gas permeable contact lenses, lens care

Introduction

Gas permeable (GP) contact lenses are used in the form of scleral and corneal lenses and for orthokeratology (ortho-k) for the correction of myopia, for other refractive disorders, and for the slowing of myopia progression.1–3 They account for about 10% of fits worldwide (with considerable intercountry variation) and hold a steadily increasing share of ortho-k lenses.4 CLEAR CARE (also known as AOSEPT PLUS) is a 3% hydrogen peroxide cleaning and disinfecting solution for contact lenses (Alcon Laboratories, LLC, Fort Worth, TX, USA) in which, simultaneously with disinfection, a catalytic “disc” inside the case gradually reduces the peroxide to water and oxygen over six hours, leaving the lenses stored in phosphate buffered saline and ready for use. A more recent version, CLEAR CARE PLUS (CCP), also known as AOSEPT PLUS with HydraGlyde, has an additional wetting agent. Both solutions are indicated for the cleaning, disinfection, and storage of soft (hydrophilic) contact lenses (including silicone hydrogel lenses) and GP contact lenses.

In light of the increasing use of GP scleral and ortho-k lenses for myopia and other refractive disorders and/or for the control of myopia progression, this article reviews the scientific data pertaining to the use of CCP with GP lenses. Two types of commonly used GP lens materials were assessed: silicone acrylate (Boston® II [itafocon A]; Bausch + Lomb, Rochester, NY) and fluorosilicone acrylate (Boston® XO [hexafocon A]; Bausch + Lomb, Rochester, NY). These two types of lens materials are required by the International Standard Organization (ISO) for standard regimen and lens compatibility testing.5,6 Three main areas will be examined in the paper: effectiveness as a disinfectant, compatibility with GP lens material, and indications for use by contact lens wearers.

Antimicrobial Efficacy

A contact lens solution must comply with the requirements of ISO 14729, Ophthalmic optics – Contact lens care products – Microbiological requirements and test methods for products and regimens for hygienic management of contact lenses.5 In the ISO 14729 antimicrobial activity test (Stand-alone), a solution challenged with 105–106 colony forming unit (CFU)/mL of five ISO representative microorganisms is assessed for microbial load at 25%, 50%, 75%, and 100% of the recommended disinfection time (DT). The ISO panel of microorganisms includes one Gram-positive and two Gram-negative bacteria, a yeast, and a mold (Table 1).

Table 1 Microorganisms Required in the ISO 14729 Stand-Alone and Regimen Tests

To meet the highest requirement (primary criteria), a solution is required to reduce the microbial load for each of three bacteria by 3 logs, yeast by 1 log, and mold by 1 log at DT (with no increase >0.5 log for yeast or mold at 400% DT). A product may be labeled as a disinfecting solution when it meets the primary criteria. For “no rub” solutions, organic soil is required in the Stand-alone and Regimen tests. Organic soil mimics organic matter and deposits on lenses that may be present in actual patient wear situations.5 The Regimen test is designed to evaluate the effectiveness of the solution regimen (eg, rubbing, and/or rinsing, soaking steps) at reducing microorganisms and organic matter on contact lenses. A solution passes the Regimen test if the average CFU per lens and soaking solution recovered at DT is <10 for all five ISO microorganisms per contact lens type (Table 2). ISO 14729 does not require Stand-alone or Regimen testing with clinically relevant bacteria from adverse events (AE) or Acanthamoeba species (spp).

Table 2 ISO 14729:2001 Antimicrobial Activity Test Criteria

Gabriel et al7,8 reported on the antimicrobial efficacy of CCP in the Stand-alone and Regimen tests. Solutions in CCP lens cases with neutralizing discs were inoculated with organisms and evaluated for microbial loads at DT. The Stand-alone tests were carried out with and without organic soil (the results with organic soil are considered the worst-case scenario for disinfection, as organic soil can interfere with disinfecting agents in the solution5). Figure 1 shows the results for the Stand-alone at DT. The antimicrobial efficacy of CCP exceeds the primary criteria of the ISO Stand-alone requirements.

Figure 1 Antimicrobial efficacy of CCP against ISO 14729 microorganisms. CCP exceeds the primary Stand-alone criteria against bacteria, yeast and mold. Adapted with permission from Wolters Kluwer Health, Inc.: Gabriel MM, McAnally C, Bartelll J, et al. Biocidal efficacy of a hydrogen peroxide lens care solution incorporating a novel wetting agent. Eye Contact Lens. 2019;45(3):164–170. © 2018 Contact Lens Association of Ophthalmologists.7

Abbreviations: CCP, CLEAR CARE PLUS; ISO, International Standard Organization.

For the Regimen test, GP lenses inoculated with ISO microorganisms were placed in basket lens holders, rinsed for five seconds with CCP solution, and soaked in CCP solution in the lens case with the neutralizing disc for at least 6 hours. Lenses and solutions were evaluated for microbial loads at DT. Table 3 shows the results of the Regimen tests with GP lenses at DT.

Table 3 Results of the Regimen Test for CCP Used with GP Lenses

The antimicrobial efficacy of a disinfecting solution can be further challenged using clinically relevant ocular strains isolated from patients with adverse events (AEs), as these strains may be more resistant to disinfection than laboratory strains. Gabriel et al7 tested CCP against two clinically relevant ocular isolates from infections of P. aeruginosa and one strain each of Stenotrophomonas maltophilia and S. aureus. CCP reduced all clinically relevant bacterial strains by >4.5 logs, therefore exceeding the ISO 3-log reduction requirement for bacteria (Figure 2).

Figure 2 Antimicrobial efficacy of CCP against clinically relevant microorganisms. CCP exceeds the primary Stand-alone criteria against bacteria. Adapted with permission from Wolters Kluwer Health, Inc.:  Gabriel MM, McAnally C, Bartelll J, et al. Biocidal efficacy of a hydrogen peroxide lens care solution incorporating a novel wetting agent. Eye Contact Lens. 2019;45(3):164–170. © 2018 Contact Lens Association of Ophthalmologists.7

Abbreviation: CCP, CLEAR CARE PLUS.

The most rigorous test of antimicrobial efficacy is to challenge the solution with Acanthamoeba spp, as Acanthamoeba are resilient in both their trophozoite and particularly their cyst form. CCP was evaluated by a modified Stand-alone test using strains of the T4 genotype isolated from keratitis cases, A. castellanii ATCC 50370 and A. polyphaga ATCC 30461. Strains belonging to the T4 genotype are most commonly associated with Acanthamoeba keratitis.7 While there are no standards for determining lens care solution efficacy against Acanthamoeba spp, Figure 3 shows that CCP reduces trophozoites by ≥4.0 logs (99.99%) and cysts by >2.0 logs (99%) at DT. The superior efficacy of the CCP hydrogen peroxide lens care system compared with multipurpose solutions (MPS) against Acanthamoeba spp is supported by previous studies.9,10

Figure 3 Antimicrobial efficacy of CCP against trophozoites and cysts for two strains of Acanthamoeba. CCP reduces trophozoites of two Acanthamoeba strains by ≥99.99% and cysts of two Acanthamoeba strains by >99%. Adapted with permission from Wolters Kluwer Health, Inc.: Gabriel MM, McAnally C, Bartelll J, et al. Biocidal efficacy of a hydrogen peroxide lens care solution incorporating a novel wetting agent. Eye Contact Lens. 2019;45(3):164–170. © 2018 Contact Lens Association of Ophthalmologists.7

Abbreviation: CCP, CLEAR CARE PLUS.

Compatibility

One concern with exposing contact lenses to any form of disinfection system is whether the solution might have an effect on the lens material or cause changes in lens parameters. Lens compatibility testing with the indicated types of lenses is a standard part of the regulatory review and approval process for any contact lens care solution.

Lens compatibility testing was conducted in accordance with ISO 11981.6 CCP was tested over 30 cycles with two GP contact lenses, Boston II (silicone acrylate) and Boston XO (fluorosilicone acrylate). Sixteen lenses of each type covering the power range from −10.25D to +11.50D were used in this study. Initially all lenses were soaked in ISO saline (isotonic standard saline solution) for at least one hour to equilibrate them before being inspected. Lenses were inspected for physical appearance to ensure they were free of nicks, cuts, and visual discoloration. For all lenses, the base curves, diameters, and powers were measured at baseline. Before each disinfection cycle, all lenses were incubated for 30 minutes at 37 °C in an artificial tear solution containing salts, lysozyme, albumin, and immunoglobulin. The lenses were then placed in basket lens holders, rinsed for five seconds with CCP solution, and soaked in CCP solution in the case with the neutralizing disc for at least 6 hours. Thirty (30) treatment cycles were conducted to represent a full month of daily use of the CCP lens care solution. After 30 cycles, the lenses were soaked in ISO saline for at least one hour for post-cycle testing. Then a final measurement of all lens parameters was performed. The baseline and final measurements were compared to determine the average change in each measurement. After 30 disinfection cycles, it was determined that the lenses were still free of nicks, cuts, and visual discoloration, and that all lens parameter measurements were within acceptable limits (Table 4). CCP solution did not affect the physical and optical parameters of GP lenses evaluated in the study, indicating that CCP solution is compatible with silicone acrylate and fluorosilicone acrylate GP lenses.

Table 4 Results of Parameter Measurements for Two GP Lenses After 30x Disinfection Cycles with CCP

Safety Performance

After demonstrating CCP antimicrobial efficacy as a disinfecting solution and its compatibility with GP contact lenses, the final test is to examine its performance with patients in clinical use. A 3-month, prospective, randomized, multicenter, single (observer)-masked, parallel-group study was conducted with 106 volunteer subjects with normal eyes (apart from a corrected refractive error) with a history of successful wear of either Boston II (silicone acrylate) or Boston XO (fluorosilicone acrylate) GP contact lenses. Subjects were randomized to use either the test solution, CCP (n=71 subjects) or the control solution, Boston Simplus Multi-action Solution (MAS) (n=35 subjects) daily for at least 8 hours a day for 90 days. The bottles of the test and control solutions were labeled as “Disinfecting Solution” including subject number, protocol number, fill volume, storage conditions, and the product is for investigational use only. Following the baseline visit, at which subjects were given the solutions and instructions for use, subjects were followed up at 7, 30, 60, and 90 days. At each visit, wear time and symptoms (comfort, vision, and handling) were recorded and visual acuity, contact lens fit, and lens over-refraction were evaluated. The contact lenses were inspected using a modified Rudko lens classification system and an anterior segment slit lamp examination including fluorescein staining was carried out. At the end of the study, the collected lenses were analyzed for level of lysozyme deposition using liquid chromatography. Procedures were in place for the reporting and management of any potential AEs.

There were no significant differences in wear times from day 0 in either group, except for the control MPS at 60 days, where it was longer (13.3 hours vs 11.8 hours) (Figure 4). Visual acuities did not change significantly for either group during the study. There were no biomicroscopy findings greater than mild (grade 2) in either group.

Figure 4 Difference in wearing times for CCP and the control MAS over 90 days. One result at day 60 was statistically significant (p < 0.05), but the overall changes over time were comparable.

Abbreviations: CCP, CLEAR CARE PLUS; MAS, multi-action solution.

A total of 21 ocular AEs in 7 of the total 71 subjects were reported in the test group and 7 AEs in 2 of 35 subjects in the control group (p=NS). The most frequently reported AE was eye irritation; all were mild to moderate and all resolved/recovered. Two subjects discontinued voluntarily from the test group during the first week. Four lenses in the test group were replaced (three lost, one damaged) as were two in the control group (one lost, one damaged).

The percentage of lenses that were visibly clean was not significantly different between the test and control groups at the p = 0.05 level, nor were the levels for film deposits, crystalline deposits, and area of the lens covered by deposits (Figure 5). The average amount of residual lysozyme per lens at day 90 was 0.2 μg for both lens care systems.

Figure 5 Percent of visibly clean contact lenses at each visit over 90 days. The percentage of lenses that were visibly clean was not significantly different between the CCP/AOSEPT with HydraGlyde and the MAS control groups at the p = 0.05 level, nor were the levels for film deposits, crystalline deposits, and area of the lens covered by deposits.

Abbreviations: CCP, CLEAR CARE PLUS; MAS, multi-action solution.

In this study, CCP performed similarly to and was found to be as effective as Boston Simplus MAS based on the assessments of cleanliness, visual acuity, average lens wearing time, lens replacements, and symptoms/problems/complaints related to comfort, vision, and handling.

Discussion

Hydrogen peroxide lens care solutions kill microorganisms by producing free radicals that destroy cell membranes and essential cell components.11,12 This contrasts with MPS systems that use polyhexamethylene biguanide (PHMB), which acts on bacterial chromosomes12,13 or with alexidine and polyquaternium-1 (PQ), which interact with cell membranes and disrupt the membrane structure.12–14 Irrespective of mechanism, the disinfecting solutions must be capable of killing a broad range of microorganisms as prescribed by ISO and FDA standards.5,15 The disinfection tests are typically carried out against planktonic (floating in liquid) microorganisms, whereas it is known that, once adherent to a surface, bacteria will cover themselves with a protective biofilm that renders them more difficult to kill. Testing against bacterial and fungal biofilms showed that hydrogen peroxide disinfection performs better than a range of MPS.16–18

One concern with the use of hydrogen peroxide systems for contact lens disinfection is that the H2O2 may not be fully neutralized, which might lead to ocular irritation for contact lens wearers. Neutralization of CCP by the catalytic disc results in residual peroxide levels of 5 to 20 ppm of hydrogen peroxide,19 well below the human detection thresholds of 267–282 ppm in hydrogel lenses and 812 ppm when instilled as a drop into the eye.20 As the water content of GP lenses is typically less than 1%, exposure would be restricted to the small volume of solution on the surface of the lenses. Furthermore, hydrogen peroxide is a common by-product of normal physiological processes and a part of the body’s normal defenses against microbes. The conjunctival sac is well equipped with enzymes such as catalase, superoxide dismutase, and glutathione peroxidase to rapidly neutralize any low levels of peroxide residuals on the lenses.21

Hydrogen peroxide cleaning and disinfecting systems have been widely trusted and used by contact lens wearers since the 1970s19 and they still have a strong presence in the market because of their combination of a strong disinfection capability with low sensitivity from the absence of disinfectant after neutralization.

A recently published review of scientific and clinical evidence provides an overview of the ease of use and compliance, lens and ocular tissue compatibility, disinfection efficacy, and ocular surface safety of hydrogen peroxide systems. The publication suggested that hydrogen peroxide maybe particularly relevant for GP lens wearers due to its ability to remove deposits and penetrate biofilms.22

Conclusion

CCP has been subjected to a large variety of tests to assess cleaning, disinfection, compatibility, and safety performance when used with GP contact lenses. CCP satisfies ISO 14729 and FDA lens care solution efficacy requirements for the Stand-alone test, and the Regimen test with GP lenses, and has been shown to be effective against clinically relevant isolates from AEs and Acanthamoeba trophozoites and cysts. Compatibility of CCP for use with GP lenses has been demonstrated. Clinical trials have established safety when used with GP lenses, and these are supported by additional studies reported in the literature, confirming its competence for the labeled indication with these lenses.

Acknowledgments

We would like to acknowledge Tim Grant, who advocated providing a review of scientific evidence for using hydrogen peroxide for disinfection of GP contact lenses. Medical writing and editing assistance support were provided by Ross Grant (Toolbox Training and Consultancy, Zurich, Switzerland) and editorial support post-submission was provided by BelMed, Inc., both funded by Alcon. 

Disclosure

The authors are employees of Alcon Research, LLC, Johns Creek, GA, and Fort Worth TX, USA. The authors report no other conflicts of interest in this work.

References

1. Smith MJ, Walline JJ. Controlling myopia progression in children and adolescents. Adolesc Health Med Ther. 2015;6:133–140.

2. Aller TA. Clinical measurement of progressive myopia. Eye. 2014;28(2):147–153. doi:10.1038/eye.2013.259

3. Kakita T, Hiraoka T, Oshika T. Influence of overnight orthokeratology on axial elongation in childhood myopia. Invest Ophthalmol Vis Sci. 2011;52(5):2170–2174. doi:10.1167/iovs.10-5485

4. Morgan PB, Woods CA, Tranoudis JG, et al. International contact lens prescribing in 2019. Contact Lens Spectr. 2020;35:26–32.

5. ISO 14729 2001/Amd1 2010 ophthalmic optics - contact lens care products – microbiological requirements and test methods for products and regimens for hygienic management of contact lenses; 2001. Available from: https://www.iso.org/standard/52491.html. Accessed August 5, 2020.

6. ISO 11981: ophthalmic optics – contact lenses and contact lens care products – determination of physical compatibility of contact lens care products with contact lenses; 2009. Available from: https://www.iso.org/standard/52491.html. Accessed August 5, 2020.

7. Gabriel MM, McAnally C, Bartelll J, et al. Biocidal efficacy of a hydrogen peroxide lens care solution incorporating a novel wetting agent. Eye Contact Lens. 2019;45(3):164–170. doi:10.1097/ICL.0000000000000549

8. Gabriel MM, Bartell J, Walters R, et al. Biocidal efficacy of Clear Care Plus against bacteria, fungi, and Acanthamoeba species with rigid gas permeable lenses. Poster presented at: Global Specialty Lens Symposium, Las Vegas, NV, USA; January 21–24, 2016.

9. Mowrey-McKee M, George M. Contact lens solution efficacy against Acanthamoeba castellanii. Eye Contact Lens. 2007;33(5):211–215. doi:10.1097/ICL.0b013e31805d8662

10. Johnston SP, Sriram R, Qvarnstrom Y, et al. Resistance of Acanthamoeba cysts to disinfection in multiple contact lens solutions. J Clin Microbiol. 2009;47(7):2040–2045. doi:10.1128/JCM.00575-09

11. Lowe R, Brennan NA. Hydrogen peroxide disinfection of hydrogel contact lenses: an overview. Clin Exp Optom. 1987;70(6):190–197. doi:10.1111/j.1444-0938.1987.tb04244.x

12. Ahearn DG, Gabriel MM. Disinfection of contact lenses. In: Block S, editor. Disinfection, Sterilization and Preservatives. 5th ed. Baltimore: Williams & Wilkins; 2001:1105–1114.

13. Chindera K, Mahato M, Kumar Sharma A, et al. The antimicrobial polymer PHMB enters cells and selectively condenses bacterial chromosomes. Sci Rep. 2016;6:23121. doi:10.1038/srep23121

14. McDonnell G, Russell AD. Antiseptics and disinfectants: activity, action, and resistance. Clin Microbiol Rev. 1999;12(1):147–179.

15. US Department of Health and Human Services, Food and Drug Administration, Center for Devices and Radiological Health, Contact Lens Branch. FDA Guidelines, May 1997 Premarket Notification (510(k0)) Guidance Document for Contact Lens Care Products. Rockville, MD; 1997.

16. Retuerto MA, Szczotka-Flynn L, Ho D, Mukherjee P, Ghannoum MA. Efficacy of care solutions against contact lens-associated Fusarium biofilms. Opt Vis Sci. 2012;89(4):382–391. doi:10.1097/OPX.0b013e31824cb754

17. Szczotka-Flynn L, Imamura Y, Chandra J, et al. Increased resistance of contact lens-related bacterial biofilms to antimicrobial activity of soft contact lens care solutions. Cornea. 2009;28(8):918–926. 1lfC. doi:10.1097/ICO.0b013e3181a81835

18. Wilson LA, Sawant AD, Ahearn DG. Comparative efficacies of soft contact lens disinfectant solutions against microbial films in lens cases. Arch Ophthalmol. 1991;109(8):1155–1157. doi:10.1001/archopht.1991.01080080115043

19. Chalmers R. A fresh look at one-step hydrogen peroxide lens disinfection. Rev Optom. 2014;suppl:1–8.

20. Chalmers RL, McNally J. Ocular detection threshold for hydrogen peroxide: drops vs lenses. Int Contact Lens Clin. 1988;15:351–367. 2777l.

21. Chalmers RL. A review of the metabolism of hydrogen peroxide by external ocular structures. Int Contact Lens Clin. 1996;22(7/8):143–146. doi:10.1016/0892-8967(95)00038-V

22. Nichols JJ, Chalmers RL, Dumbleton K, et al. The case for using hydrogen peroxide contact lens care solutions. Eye Contact Lens. 2019;45(2):69–82. doi:10.1097/ICL.0000000000000542

Creative Commons License © 2021 The Author(s). This work is published and licensed by Dove Medical Press Limited. The full terms of this license are available at https://www.dovepress.com/terms.php and incorporate the Creative Commons Attribution - Non Commercial (unported, v3.0) License. By accessing the work you hereby accept the Terms. Non-commercial uses of the work are permitted without any further permission from Dove Medical Press Limited, provided the work is properly attributed. For permission for commercial use of this work, please see paragraphs 4.2 and 5 of our Terms.