Microbiology, Lens Care and Maintenance

Morphology (see Fig. 4.2 )

• ▪

  Spherical (cocci). The morphology of cells depends on how single cells divide. Possible options include:

  • ▪

    if cocci divide in a single plane, they form pairs ( diplococci , e.g. Neisseria spp.) or chains (e.g. Streptococcus spp.).

  • ▪

    if cocci divide in two planes, they form a group of four ( tetrads , e.g. Micrococcus spp.).

  • ▪

    if cocci divide in three planes, they form a cluster of eight either as a cube ( sarcinae ) or as a cluster (e.g. Staphylococcus spp.).

• ▪

  Cylindrical ( bacilli or rods , e.g. Pseudomonas spp.). Again these may take several forms:

  • ▪

    Coccobacilli are short rods with a more rounded appearance (e.g. Acinetobacter spp.).

  • ▪

    Filamentous rods that grow as elongated forms.

  • ▪

    Vibrios that look like commas (e.g. Vibrio cholerae ).

• ▪

  Helical, known as spirochaetes.

These different morphologies are illustrated in Fig. 4.2a and b . *

* For further information see: http://www.cdc.gov/od/ohs/biosfty/bmb14/bmb14s7d.htm

Bacteria may also be differentiated by their carbohydrate metabolism, protein metabolism, enzyme production or other specific biochemical reactions (biotyping). For microorganisms that are biochemically similar, other methods of typing include:

• ▪

  Antibiogram typing . This method is based on the microorganism's susceptibility to different antibiotics.

• ▪

  Bacteriophage typing. Differentiation on the basis of the microorganism's susceptibility to various bacterial viruses, which is used commonly to differentiate between strains of Staphylococcus aureus .

• ▪

  Bacteriocin typing . Differentiation on the basis of inhibitory protein (bacteriocin or pyocin) production. Certain microorganisms, including Pseudomonas aeruginosa, produce proteins that inhibit the growth of other members of the same species.

• ▪

  Serotyping. Differentiation on the basis of antigenic structure. This method is used to differentiate between strains of, for example, P. aeruginosa and Legionella pneumophila .

• ▪

  Molecular typing. These techniques involve differentiation between microorganisms at the DNA level and have been used for a wide range of species. Such molecular biology methods include random amplified polymorphic DNA (RAPD) and restriction fragment length polymorphism (RFLP) techniques. Both methods have been used in differentiating species of organisms derived from the ocular surface. The polymerase chain reaction (PCR) provides a means for amplification of DNA sequences of microorganisms.

Cell Wall

The Gram staining procedure involves sequentially staining a heat-fixed smear of bacterial cells with crystal violet and iodine, then decolourising with an organic solvent and counterstaining. Gram-positive bacteria resist decolourisation and remain stained purple. Gram-negative bacteria decolourise and take up a red/pink counterstain. Fig. 4.3 illustrates Gram-positive and Gram-negative bacilli and cocci. Table 4.2 shows the difference between the two.

Bacteria are grouped by their Gram-staining reaction, which reflects the structure of the cell wall. The cell wall of Gram-positive microorganisms comprises a cytoplasmic membrane surrounded by a thick peptidoglycan layer (a mucopeptide) cross-linked with peptide subunits that give rigidity to the structure and interspersed with (lipo-) teichoic or teichuronic acid.

In contrast, Gram-negative microorganisms have a cytoplasmic membrane with a smaller peptidoglycan layer, surrounded by an outer protein membrane and lipopolysaccharide (LPS) enclosing the periplasmic space. In the eye, this difference is important in defence since the tear protein lysozyme cleaves peptidoglycan and causes bacterial death, either by allowing other bactericidal proteins to penetrate the cell or by causing osmotic death. Peptidoglycan damage is more of a problem for Gram-positive microorganisms, and lysozyme is much less effective against Gram-negative bacteria that are protected by their outer wall (that is impermeable to enzymes).

Outside the cell wall, there may be other external structures present such as flagella, pili and capsules. Flagella are filaments of the protein flagellin, responsible for bacterial motility. Pili are shorter filaments of the protein pilin that emerge from the cytoplasmic membrane which are responsible for bacterial adhesion and the transfer of nonchromosomal genetic material, such as plasmids, ^†

† Plasmid – a small circle of DNA found within bacteria.

between bacteria. These are general gene-carrying, mobile DNA elements found in the cell cytoplasm that are not essential for bacterial survival but that provide some selective advantage (e.g. antimicrobial resistance).

Capsules are frequently a polysaccharide matrix composing the outermost layer of certain bacteria. Capsules are a major determinant in the virulence of a microorganism that act by protecting the bacteria from phagocytosis and from other antimicrobial agents. Capsules also play a role in the binding to host tissue.

Growth Requirements

Bacteria can be further classified according to their environmental requirements for growth. These could include growth temperature, oxygen requirements, pH, salinity and micronutrients.

The temperature ranges for optimal growth are as follows:

• ▪

  thermophilic microorganisms: 55–80°C

• ▪

  mesophilic microorganisms: 25–40°C

• ▪

  psychrophilic microorganisms: below 20°C

Atmospheric requirements can be classified as follows:

• ▪

  aerobic microorganisms that require oxygen for growth

• ▪

  facultative anaerobic microorganisms that grow in the presence or absence of oxygen

• ▪

  anaerobic microorganisms that grow only in the absence of oxygen

• ▪

  microaerophilic microorganisms that grow in the presence of trace oxygen and carbon dioxide.

External ocular infections tend to be caused by mesophilic microorganisms that may be aerobes, facultative anaerobes or microaerophilic microorganisms.

Bacteria and Disease

Bacteria may cause disease either by:

• ▪

  direct invasion of tissue and subsequent replication of microorganisms

• ▪

  toxin or enzyme production that may in turn activate the immune system causing an inflammatory tissue response. Dead or dying bacteria also release toxins.

In diseases associated with Gram-negative microorganisms, endotoxin has been implicated as a cause of major tissue damage. Endotoxin is an outer membrane component of Gram-negative microorganisms composed of lipopolysaccharide that is known to cause antibody and cytokine production, neutrophil migration and complement activation.

Fungi and Disease

Fungi release spores into the environment that are carried by air or water. Spores are highly resistant to environmental factors and can survive extremes of temperature and pH. This resistance is due partly to surface components, such as hydrophobic glycoproteins or lipoglycoproteins, that also help dissemination. They are ubiquitous in the environment, are found on skin and are ingested or inhaled frequently. Despite their frequency in the environment, fungal disease is rare and requires the spores to penetrate the host tissue and germinate.

Species pathogenic in the eye include filamentous fungi, Aspergillus spp., Fusarium spp. and the yeast Candida spp. Historically, fungi have not been associated with contact lens–related infections; however, an international outbreak of Fusarium spp. keratitis in 2006–2007 was attributed to limited antimicrobial efficacy of a specific contact lens solution ( ) (See: Product Recalls (2006/2007) in Section 8 , History, available at: https://expertconsult.inkling.com/ ).

Viruses and Disease

Viruses can produce disease in several ways:

• ▪

  Directly by inhibiting cell metabolism and synthesis. Cells infected by viruses lyse, and this can lead to temporary or permanent loss of function.

• ▪

  Indirectly by compromising host defences so that opportunistic microorganisms such as bacteria can colonise. One example of this is the influenza virus that damages the respiratory epithelium and cilia so that the surface cannot be cleared of bacteria. Bacteria such as Haemophilus influenzae are then able to adhere to the damaged tissue and to colonise and produce disease.

• ▪

  By inducing tumour formation ( oncogenic viruses). This is controversial, but both DNA and RNA viruses carry genes closely related to host cell genes that are able to transform cells and alter their physiological properties.

Prions and Disease

Prions cause cross-species neurodegenerative diseases known as transmissible spongiform encephalopathies in humans and animals. The most common acquired human prion diseases include Creutzfeldt-Jakob disease (CJD) and new variant Creutzfeldt-Jakob disease acquired through eating infected cattle meat and kuru (ritual cannibalism in New Guinea). Iatrogenic CJD has been reported following administration of prion-containing growth hormone and transplantation of prion-containing nervous system grafts. There was one proven case ( ) and three possible cases following corneal transplantation ( , , ). *

* For further information see: https://www.cdc.gov/prions/cjd/index.html

For a comparison of eukaryotes, ^†

† Eukaryote – can be single-cell or multi-cellular and contain a nucleus surrounded by a membrane that contains DNA. Eukaryotes also contain other organelles.

prokaryotes, ^‡

‡ Prokaryote – single cells that do not contain a nucleus and contain few cell components other than pieces of DNA.

viruses and prions, see Table 4.3 .

Normal Ocular Biota (Living Organisms Within the Eye)

Historically, it has been accepted that the external ocular surface is sparsely colonised by culturable organisms, and microorganisms are removed by the normal ocular defence mechanisms rather than leading to persistent and increased colonisation over time.

The most common microorganisms isolated from the eyelids and conjunctiva are Gram-positive bacteria, specifically coagulase-negative staphylococci, Propionibacterium spp. and Corynebacterium spp. Other bacterial species include Staphylococcus aureus, Micrococcus spp., Bacillus spp. and Bacteroides spp. ( , , , , , ). The conjunctival fornices may harbour small numbers of anaerobic organisms, with Propionibacterium and Peptostreptococcus being the most common genera ( , ). Gram-negative microorganisms are isolated in less than 5% of cases and tend to be present as transient microorganisms rather than persistent colonisers in normal healthy eyes. The cornea and anterior chamber have been considered to be sterile, although more recently, molecular surveillance techniques challenge this assumption for the cornea.

Fungi are less common, although regional variations have been reported, with fungal recovery from the eyelids occurring in 2–52% of samples and in 2–28% of conjunctival samples ( , ). An increased recovery rate of fungi from the ocular surface has been reported using PCR for the detection of fungal DNA ( ).

The advent of molecular techniques, particularly 16S ribosomal DNA amplification and sequencing, have shown a much more diverse microbiome ^§

§ Microbiome – the microorganisms in a particular environment; in this case the eye.

at the ocular surface than revealed by conventional culture of viable organisms ( , , , ). Interpretation of these findings is challenging given the impact of possible DNA contamination from transient and other organisms. With the development of high-throughput DNA-sequencing techniques, there is likely to be further exploration of the ocular surface microbiome and a better understanding of whether a stable microbiome exists and how this may change over time and in different states of the disease ( , ).

Microorganisms and Eye Disease

Table 4.4 summarises the common causative microorganisms for different ocular diseases.

General Concepts in Disinfection Efficacy

The efficacy of many chemical systems is related to the concentration of the active agent, its contact time and the form of delivery. There is invariably a trade-off between antimicrobial activity and ocular toxicity, and comfort and convenience.

Many disinfectants, including contact lens solutions, are neutralised by organic materials ( ) so that binding to organic material effectively reduces the concentration of the antimicrobial agent. Bacterial endospores are more resistant to disinfectants than are vegetative organisms due to their lower water content and slower metabolism. Not all microorganisms are equally susceptible to disinfection. Generally, susceptibility is as follows: viruses with lipid envelopes > vegetative bacteria > fungi > non-enveloped viruses > mycobacteria > bacterial spores > cyst > prions.

Note: a lipid virus has an envelope (or membrane) which is largely lipid and prone to desiccation so more susceptible to sterilisation.

Microorganisms can acquire resistance to disinfectants:

• ▪

  through transfer of nonchromosomal genetic material on plasmids

• ▪

  altering the binding sites for antimicrobials as happen through phosphorylation (adding phosphate to an organic compound)

• ▪

  altering the drug enzymatically

• ▪

  developing effective pumps for removal of the drug.

Organisms with a complex cell wall composition tend to be more resistant than those with a simple cell wall structure. Certain bacteria (e.g. staphylococci) and fungi produce the enzyme catalase, which neutralises hydrogen peroxide. This may account for higher contamination rates with Gram-positive organisms in one-step peroxide systems ( ). Acquired resistance of Serratia marcescens to solutions containing chlorhexidine and benzalkonium chloride in rigid lens solutions has been documented ( , ), and reported resistance of cytotoxic strains of Pseudomonas aeruginosa to hydrogel lens solutions containing polyaminopropyl biguanide (PAPB) and polymeric quaternary ammonium compounds (QAC).

Product Recalls (2006/2007)

For outbreaks of Fusarium spp. and Acanthamoeba spp., see Section 8 , History, available at: https://expertconsult.inkling.com/ .

Research by suggests that a solution’s formulation plays a significant role in the induction of Acanthamoeba spp. encystment. While they implicated propylene glycol, the fact that not all solutions containing propylene glycol induce encystment implies that the situation might be multifactorial.

Environmental factors that promote the growth of Acanthamoeba spp. were implicated in case-control studies in the UK where Acanthamoeba keratitis (AK) is associated with ‘hard’ water ( ) and loft-located water tank storage systems. It is likely that in those conditions, bacterial biofilms form that are a food source for Acanthamoeba spp.

The avoidance of tap water in all contact lens use has been a consistent safety message in recent years ( ). Furthermore, advice included in contact lens solution patient instruction inserts advocates complete replacement of CL solutions after each and every disinfection cycle ( ). A campaign by the British Contact Lens Association (BCLA) against the use of tap water has also been instigated ( Fig. 4.6 ).

In-Office Disinfection of Trial Lenses ^*

* See ISO/TS 19979 : 2014 (E) Ophthalmic optics – contact lenses – Hygiene management of multi-patient use trial contact lenses.

To limit the transfer of microorganisms among patients, trial lenses ideally should be used once and discarded. Where this is not possible, in-office disinfection needs to be effective against bacteria, fungi, viruses and Acanthamoeba .

Another concern is the theoretical risk for transmission of vCJD via trial lens fitting or through other ophthalmic procedures.

Although it appears that the risk for transmission of prion infections by contaminated lenses is negligible ( ), the Department of Health and the College of Optometrists in the UK recommend soaking the lenses in 1% sodium hypochlorite for 10 minutes. For the complete recommendations see https://guidance.college-optometrists.org/guidance-contents/safety-and-quality-domain/infection-control/the-re-use-of-contact-lenses-and-ophthalmic-devices/

It is not clear whether soft lens parameters are stable with this process, although RGP lenses do appear to be. For patients in a high-risk category for vCJD, disposal of the device or lens following use is recommended.

Heat Disinfection

Removal of agents other than prions can be achieved with heat disinfection using sterile saline. This provides:

• ▪

  a rapid, cheap and effective method of lens and vial disinfection

• ▪

  an effective method against bacteria, fungi, viruses and Acanthamoeba, including cysts, utilising temperatures of 78–90°C for 20 minutes to 1 hour ( , ).

Drawbacks of heat disinfection of trial lenses include:

• ▪

  regrowth of organisms over time

• ▪

  the stability of lens parameters, particularly high–water-content lenses

• ▪

  reduced lens life

• ▪

  the periodic requirement to ensure that the disinfection cycle for in-office heating units maintains the required temperature for an appropriate period (i.e. procedure validation).

Hydrogen Peroxide

A 3% concentration of hydrogen peroxide is an effective method for the removal of bacteria, fungi, viruses and Acanthamoeba including cysts ( ). Exposure periods ranging from 10 minutes to 4 hours have been recommended, depending on the organism type. Non-neutralised peroxide has activity against organisms within a biofilm ( , ).

Drawbacks of hydrogen peroxide in trial lens disinfection include:

• ▪

  the requirement for a neutralisation step before use

• ▪

  leakage of fluid from one-step cases ( )

• ▪

  regrowth of organisms in neutralised peroxide ( , )

• ▪

  the need for a vented case (see later).

Recommended Methods of Disinfection

The US Centers for Disease Control and Prevention (CDC) recommends disinfection of trial lenses with hydrogen peroxide or heat to prevent transmission of HIV ( ). For hydrogel lenses, there are no recommended decontamination procedures for removal of prions, and the consensus appears to be to discard the lenses wherever possible. If this is not possible, patients should be informed of the risks associated with multiple-use lenses, and this should be documented.

The recommended procedure for hydrogel trial lenses is as follows:

• ▪

  Clean and rinse on removal. Rub lenses for at least 20 seconds on each side of the lens with an alcohol-based cleaner, such as Oté (Oté Pharma), or a mildly abrasive cleaner followed by a sterile-saline rinse. This is associated with at least a 2-log unit reduction in viable organisms ( , ) and also removes HIV from lens surfaces ( ).

• ▪

  Soak in 3% hydrogen peroxide for at least 2–3 hours, and then neutralise for 10–60 minutes.

• ▪

  Store in a cold chemical system with redisinfection every 30 days ( ). To prevent contamination while handling, use the same storage container and refill with the chemical system ( ).

• ▪

  Replace lenses annually or as specified by the manufacturer.

For rigid trial lenses ( ), rub lenses for at least 20 seconds on each side of the lens with an alcohol-based or mildly abrasive cleaner, followed by a sterile-saline rinse.

Then do either of the following:

• ▪

  Soak in 2% hypochlorite for 1 hour followed by rinsing with sterile saline.

• ▪

  Soak in 3% hydrogen peroxide for at least 5–10 minutes. Remove and rinse with sterile saline.

Store dry, and, prior to reuse, clean and rinse lenses as above.

Organic

• ▪

  tear proteins – mostly protein deposition remains a problem of hydrogel lens materials, and SiHy contact lenses have relatively little susceptibility to protein deposits.

• ▪

  lipids – although having only limited solubility in water, some have greater solubility in the lens polymers themselves ( ). The core component of SiHy lenses is poly[dimethyl siloxane]) (pDMS), which is lipophilic and a lipid solvent ( ). This means that deposits may be both on and in the lens matrix. Lipid deposition is greatest with materials containing vinyl pyrrolidone ( , ) and silicones, and many current SiHy lens polymers contain both.

• ▪

  mucin

• ▪

  other tear components

• ▪

  discolourations

• ▪

  finger-borne contaminants (skin lipids, dirt, microorganisms, other)

• ▪

  airborne contaminants.

Inorganic

• ▪

  occupational/industrial

  • ▪

    metallic:

    • ▪

      colours are often characteristic of the metal cation involved

    • ▪

      metal may corrode in situ (e.g. iron), leading to rust spots, pitting, and deposit protrusion.

  • ▪

    nonmetallic:

    • ▪

      may be inactive (e.g. asbestos dust)

    • ▪

      nonasbestos brake linings, disc-brake pad dust

    • ▪

      discolourations.

• ▪

  clothing residues (lint)

• ▪

  accumulation of lens care products or their derivatives

• ▪

  finger-borne contaminants

• ▪

  air-borne contaminants.

Environmental issues include:

• ▪

  workplace location and activities

• ▪

  residential location and environmental factors (e.g. proximity of accommodation to roadways, railways, factories, smokestacks)

• ▪

  commuting/travelling environment.