Abstract
Many types of antimicrobial agents have been introduced for the treatment of ocular infectious diseases. Some ocular infections have been eradicated such as smallpox, while others have been controlled by public health measures such as trachoma. The resilience of viruses and the tenacity of bacteria have led to the evolution of old diseases and the emergence of new infections. Continuous search for new antimicrobial agents for the treatment of infectious diseases is, therefore, highly desirable.
New infectious agents are discovering the human race, and the ecological changes are exposing mankind to new viruses and bacteria. In addition, air travel and disruption of geographic barriers are leading to new forms of infectious diseases.
In the twentieth century, there was a widespread false optimism that infectious diseases are eradicated by antimicrobial agents. It was soon discovered that many infections require new strategies for the treatment of ocular infections.
The new antimicrobial agents that have been introduced over the past century can be classified into four major categories including (1) antibiotics that inhibit cell wall synthesis and integrity, (2) antibiotics that inhibit and suppress cell membrane functions, (3) antibiotics that interfere the protein synthesis, and (4) antibiotics that modulate nucleic acid synthesis.
The selection of antimicrobial agents for the treatment of ocular infectious diseases is based on the most frequently encountered organisms, the pharmacokinetics of the antibiotics, the dosage required, the ocular penetration, and the cost of therapy. The stumbling blocks to safe and effective antimicrobial therapy in ocular infections include the resistance of the microorganisms, toxicity of the drug, and poor ocular penetration of antimicrobial agents.
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2.1 Introduction
The US Food and Drug Administration has approved more new antibiotics in the past 20 years than all antibiotics discovered in the twentieth century. The recent proliferation of new antibiotics has made the selection more difficult [1–5]. The selection of an antibiotic depends on the clinical findings, the most likely causative organism, the laboratory confirmation, and the pharmacokinetics of the drug.
The purpose of this chapter is to put in the hands of the ophthalmologist a concise approach to the selection of topical or systemic antimicrobial agents in the management of infections of the eye. This would provide practical, concise, and objective information on antimicrobial agents used in the treatment of infections of the eye. The information is useful as a rapid reference for the eye care practitioner. The use of antibiotics in ocular infection can be preventive, preemptive, curative, or prophylaxis. The guidelines for the proper use of antimicrobial agents in ophthalmology are outlined (Table 2.1).
The dramatic decrease in the incidence of classic infectious diseases is due largely to, first, mass vaccination, which has eradicated certain infectious disease such as smallpox; second, the implementation of rigorous public health measures by many countries; and, third, the introduction of newly discovered antimicrobial agents. In the first decade of the twenty-first century, infectious diseases continue to be a serious cause of visual loss, mortality, and morbidity. We should not rest on the laurels we have won for overcoming the classic infections, but we should, rather, prepare ourselves to confront the microorganisms emerging from the degradation of our ecosystem as well as those bacteria that are becoming increasingly antibiotic resistant. Several new infectious agents have been recently identified as a cause of disease in man (Table 2.2).
Chemicals were used as early as the seventeenth century to treat infectious disease. Quinine was used for malaria, and emetine was used for amebiasis. Antibiotics, however, can cause harm as well as good. Erlich, in 1900 in Germany, introduced the concept of selective toxicity of chemicals, showing that it is possible to use an antibiotic that is toxic to the microorganism but does not harm the host. In 1929, Fleming recorded his observation that agar plates in his laboratory contaminated with Penicillium spp. were free of other bacteria such as staphylococci and went to discover penicillin. In 1935 in Germany, Domagk described sulfonamide, not only winning the Nobel Prize in 1939 but also launching a new era of antimicrobial agents. It was not until 1940, however, when Chain and Florey used penicillin in the treatment of Streptococcus pneumoniae infections, and that was the turning point in the management of infectious diseases.
Streptomycin was described in the late 1940s; tetracyclines were launched in the early 1950s, followed by chloramphenicol and later followed by lincomycin in the 1960s. Lincomycin was described from the systematic analysis of soil samples in Lincoln, Nebraska, in the United States and was named after the state’s capital city, Lincoln. It was produced by a strain of Streptomyces lincolnensis. After this discovery, extensive soil sampling was conducted worldwide to isolate and identify antibiotic-producing organisms.
There are so many different types and generations of antibiotics. It is important, therefore, to identify those which are useful in ophthalmology and those that are not. It is of paramount importance to select the right antibiotic to treat ocular infection; fundamental to this is the identification of the organism responsible for the infection.
The initial selection of antibiotics for the treatment of ocular infections is based on the most frequently encountered organism, pharmacokinetics of the antibiotic, dosage, and cost.
The great stumbling blocks to safe and effective antibiotic therapy are resistance and toxicity, two factors which must always be taken into account when choosing an antibiotic. Cost is another factor and one that is often overlooked. It is important to be aware of the fact that some antibiotics are expensive. There have been instances of patients receiving very expensive therapy when in fact the organism responsible for their infection was sensitive to much cheaper antibiotics. The combination of antibiotic agents may be used simultaneously in the following conditions:
-
(a)
In a severe devastating vision-threatening ocular infection of unknown etiology and after lab tests have been initiated to determine a specific etiologic agent
-
(b)
If an infection is caused by more than one organism
-
(c)
The emergence of resistant strains of bacteria during the treatment
-
(d)
In case of infections caused by organisms that are known to respond better to simultaneous use of more than one antibiotic such as Toxoplasma and Acanthamoeba
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(e)
Organisms not cultured and the clinical findings are highly suggestive of infectious etiology
2.2 Mechanism of Action
Although antibiotics can be described as being either bacteriostatic or bactericidal, this is a less useful classification than the one which is based on the drug mechanism of action, namely, how and where they affect the target organism. Under this system of classification, the first group of antibiotics inhibits synthesis of the cell wall, the second group inhibits the cell membrane, the third group affects ribosomal function and protein synthesis, and the fourth group affects nucleic acid synthesis.
Topical antimicrobial agents used in ocular infections are listed in Table 2.3. The antimicrobial agents that can be compounded for the treatment of ocular infections for topical, subconjunctival, intravitreal, and intravenous are summarized in Table 2.4. Antibiotics that are used for bacterial (Table 2.5), fungal (Table 2.6), viral infections (Table 2.7) are also listed.
2.3 Antibiotics That Inhibit Cell Wall Synthesis
Several antibiotics affect the cell wall of organisms including penicillins, cephalosporins, gramicidin, and bacitracin [6–17]. Bacterial survival can be compromised without a cell wall. The cell wall protects bacteria from the environmental noxious agents and maintains the intracellular milieu. The thickness of bacterial cell walls varies: Gram-positive bacteria have thick cell walls, and Gram-negative bacteria have thin cell walls. The internal osmotic pressure of Gram-positive organisms is higher than that in Gram-negative organisms. A Gram-positive organism, in particular, is under considerable risk of death when the cell wall is compromised.
Bacterial cell wall contains peptidoglycans and ligands of alternating pyranoside residues of two amino sugars, N-acetylglucosamine and N-acetylmuramic acid (the latter is not found in mammalian cells), and is cross-linked by pentapeptide chains. Pentapeptide cross-linking gives the cell wall its rigidity; consequently, the introduction of antimicrobial agents or antibiotics that interfere with cross-linking causes the cell wall to weaken and the organism to die.
Unlike bacteria, mammalian cells do not have cell walls a selective target and an example of selective toxicity.
2.3.1 Penicillins
Penicillins are beta-lactam antibiotics. There are four generations of penicillins. The first three are important in the treatment of ocular infections. The first-generation penicillins are penicillin G and penicillinase-resistant penicillins, of which there are two types, methicillin and nafcillin. Methicillin was used to treat beta-lactamase-producing organisms. Methicillin can cause interstitial nephritis and is no longer used in most centers. The penicillins are used specifically to treat ocular infections caused by Streptococcus, Neisseria, Clostridium spp., syphilis, and Actinomyces.
The second-generation penicillins include ampicillin and amoxicillin. These antibiotics have a slightly broader spectrum than those of the first generation. The second-generation penicillins are used to treat ocular infections caused by Haemophilus species and enterococci.
The third-generation penicillins are carbenicillin and ticarcillin. Ticarcillin has been combined with clavulanic acid as a suicide inhibitor of beta-lactamase. These antibiotics occupy receptor sites on Gram-negative bacteria making them more active against Gram-negative bacteria. Until recently, carbenicillin was used to treat Pseudomonas infections. Ticarcillin has replaced carbenicillin and may be used in combination with aminoglycosides. The fourth group of penicillins comprises of mezlocillin, piperacillin and azlocillin which are derivatives of ampicillin and are similar to carbenicillin and ticarcillin. These antibiotics are also effective against Gram-negative organisms because they have a greater affinity to cell wall receptor sites in Gram-negative organisms than in Gram-positive organisms. The fourth-generation penicillins have limited role in ophthalmology. New generations of antibiotics are not necessarily better or more effective than earlier generations. Each generation of antibiotics plays a specific role and has specific indication and advantages in the treatment of infections caused by susceptible organisms.
Organisms become resistant by producing beta-lactamase. The enzyme disrupts the beta-lactam ring, rendering it ineffective. In order to counteract this, an antibiotic called clavulanic acid, produced by Streptomyces spp., has been introduced. Clavulanic acid has a very weak antibiotic effect and binds to beta-lactamase and inhibits its effects, “suicide inhibition.” Clavulanic acid has unique affinity to beta-lactamase and leads to its deactivation. The combination of clavulanic acid to existing antibiotics does not constitute a new generation of antibiotics but is a new therapeutic strategy to improve the effectiveness of existing antibiotics.
A combination of 500 mg amoxicillin and 250 mg clavulanic acid (Augmentin®) is effective against beta-lactamase-producing organisms such as Haemophilus and streptococci. The drug is used for the treatment of preseptal cellulitis in young children where Haemophilus is a common cause. Similarly, a combination of ticarcillin and clavulanic acid (Timentin®).
Cloxacillin is similar to clavulanic acid (Timentin®) in that it has strong affinity for beta-lactamase and neutralizes its effects.
2.3.2 Monobactam Antibiotics
Several examples of monobactam antibiotics are available which are Impenem meropenen, ectapenem which have wide antimicrobial activity. Impenen is effective against anaerobes, Gram-positive and Gram-negative organisms, Streptococcus pneumoniae, Streptococcus Group A, Staphylococcus aureus, Streptococcus faecalis, and Haemophilus influenzae. The minimum inhibitory concentration of imipenem to Haemophilus influenzae and Neisseria spp. is less than 0.6 μg/ml. Imipenem is also effective against Enterobacteriaceae, Pseudomonas, and Acinetobacter calcoaceticus. Imipenem has been marketed in combination with silastin. Silastin inhibits hydropeptidase, an enzyme released by the brush border of the kidney which destroys imipenem. Consequently, cilastatin prolongs the half-life of imipenem and increases the concentration of imipenem in the urine. Imipenem should not be used in conjunction with cephalosporin because of potential antagonism.
2.3.3 Cephalosporins
Cephalosporins are an important group accounting for some 50 % of all antibiotics prescribed in hospitals (Tables 2.8a and 2.8b). Over 25 cephalosporins are available, and many more are under investigation. The advantages of cephalosporins include a broad-spectrum bactericidal with selective toxicity. Cephalosporins (first generation) are effective against penicillinase-producing Staphylococcus aureus. The disadvantages of cephalosporins include low CSF level, and therefore the agents are not recommended to treat meningitis. They have limited effects against enterococci, and they may potentiate nephrotoxicity if they are used intravenously in combination with aminoglycosides.
The first generation of cephalosporins was introduced in the 1970s. One of the antibiotics in this generation is cefazolin. As with other groups of antibiotics, each generation of cephalosporins has its own spectrum: the first-generation cephalosporins are more effective against Gram-positive cocci than the third- or fourth-generation cephalosporins.
The second-generation cephalosporins include cefuroxime and cefonicid. Cefuroxime is the treatment of choice for sinus infections. It has been used intracamerally in phacoemulsification for the prevention of postoperative endophthalmitis. Unfortunately, it has no effects against Pseudomonas or other enteric Gram-negative organisms. It is a good single drug for the treatment of patients with sinusitis or orbital cellulitis as it covers most of the Gram-positive cocci (staphylococci, streptococci) as well as non-enteric Gram-negative organisms; it is also effective against Haemophilus. In addition, cefuroxime has a long half-life and can be administered intravenously twice daily. Unlike cefamandole, cefuroxime does not cause bleeding tendencies and is well tolerated. The disadvantages of cefuroxime are as follows: (1) it is not active against Pseudomonas spp., enterococci, or B. fragilis, and (2) the drug is relatively expensive. Cefaclor is for oral administration.
The third-generation cephalosporins include ceftazidime, cefotaxime, and ceftriaxone. Ceftriaxone is the drug of choice for treating Neisseria gonorrhoeae. Most current strains of N. gonorrhoeae are resistant to penicillins, and many of them are resistant to other antimicrobial agents as well. Ceftriaxone is effective against infections caused by Neisseria meningitidis. Ceftriaxone is used for the treatment of ocular infections caused by Borrelia, Leptospira, and Treponema and infections caused by Haemophilus and beta-lactamase-producing organisms. Other advantages of ceftriaxone include its long half-life and, therefore, can be used once or twice daily (unlike other cephalosporins which have to be administered three or four times daily) which makes it cost-effective. Ceftriaxone has certain disadvantages including its limited value in the treatment of infections caused by Pseudomonas spp. except when combined with aminoglycosides and has little or no effect against Staphylococcus aureus and may prolong the bleeding time.
The fourth and fifth generations of cephalosporins have so far limited use in ocular infections.
Teicoplanin (Targocid®, Sanofi Aventis Ltd.) is a glycopeptide antibiotic similar to vancomycin and is effective against Gram-positive cocci including methicillin-resistant staphylococci (MRSA) [18, 19]. The drug affects the cell wall synthesis of Gram-positive bacteria. Experience in ophthalmic infections is limited. Oral teicoplanin has been shown to be effective in the treatment of Clostridium difficile-associated pseudomembranous colitis [20].
Fumagillin is used for the treatment of corneal microsporidiosis [21]. It is compounded as eyedrops at a concentration level of 0.113 mg/ml (Leiter’s Pharmacy Inc., 1700 Park Ave #30, San Jose CA, USA, Telephone No.: 800-292-6773). It has also been shown to inhibit angiogenesis.
2.4 Antibiotics That Inhibit Cell Membrane Function
Antibiotics that inhibit cell membrane function include polymyxin B, amphotericin B, colistin, imidazoles, and polyenes. Some of these antibiotics, such as amphotericin B and the polyenes, act against fungi and do not affect bacterial cell membranes.
Polyenes bind to ergosterol, a sterol moiety in the cell membrane of fungi. Ergosterol is not present in mammalian or bacterial cell membranes.
The imidazoles act against fungi but have different modes of action from the polyenes. Imidazoles act by inhibiting ergosterol synthesis leading to disruption of cell membrane function. In addition, imidazoles inhibit cytochrome C and peroxidase and allow the intracellular accumulation of hydrogen peroxidase leading to death of the fungus. Since ergosterol is the binding site for amphotericin B, the use of imidazoles may render amphotericin B less effective by competing ergosterol in the fungal cell membrane. Polymyxins bind to phosphatidylethanolamine-rich membranes, particularly in Gram-negative organisms. They have a detergent-like effect which disrupts the cell membrane, eventually causing death of the organism.
Polymyxins are effective in treating infections caused by species of Pseudomonas as well as certain other Gram-negative organisms. Polymyxins cannot be given systemically because of nephrotoxicity [22–26].
Daptomycin is a new lipopeptide antibiotic used for the treatment of resistant Gram-positive organisms. It is produced by the fungus Streptomyces roseosporus. The trade name is Cubicin®.
It binds to the bacterial cell membrane leading to depolarization and loss of membrane function. Daptomycin may also act by inhibiting protein synthesis.
Daptomycin is effective against Gram-positive cocci and shows significant corneal penetration following 1 % topical eyedrops in rabbits [27]. Daptomycin appears to be safe and effective when given intravitreally [28].
2.5 Antibiotics That Inhibit Protein Synthesis
The third group of antibiotics consists of compounds which inhibit protein synthesis and include chloramphenicol, tetracycline, lincomycin, clindamycin, aminoglycosides, and macrolides. They are used extensively in ocular infections [22]. Binding to bacterial ribosomes by erythromycin leads to inhibition of protein synthesis. Inhibition of protein synthesis is also achieved when tetracyclines and aminoglycosides bind to 30S portion of the bacterial ribosome, while the chloramphenicols, lincomycins, and erythromycin bind to the 50S portion of the bacterial ribosome. The selectivity is partial and these antibiotics may have some toxic effect on human cells. Topical chloramphenicol, is widely used to treat ocular surface infections. There have been several reports of fatal aplastic anemia following topical administration of chloramphenicol. The incidence of idiosyncracy to chloramphenicol is not high; nonetheless, if large numbers of patients are given topical chloramphenicol, cases of fatal aplastic anemia will occur.
In other situations, the use of certain antibiotics is neither ideal nor appropriate. Approximately 30 % of staphylococci isolated from ocular infections are resistant to erythromycin. Erythromycin cannot be considered the drug of choice for the treatment of infections caused by these organisms. Fusidic acid is another antibiotic in this group and is helpful in the treatment of staphylococcal blepharitis [29, 30].
We recovered 163 staphylococcal isolates from ocular infection sites and assessed their sensitivity to different antibiotics [29]. Vancomycin was found to be the most effective antibiotic against all types of staphylococci, including Staphylococcus epidermidis and Staphylococcus aureus. The results showed that while 95 % of strains of S. epidermidis were sensitive to fusidic acid and 84 % were sensitive to bacitracin, only 45 % were sensitive to methicillin, 53 % to gentamicin, 56 % to erythromycin, and 33 % to chloramphenicol [29]. Unfortunately, resistant strains of staphylococci to fusidic acid started to appear. Currently, close to 52 % of ocular isolates of staphylococci are sensitive to fusidic acid. The topical use of antibiotics such as chloramphenicol is less effective and carries risks of systemic adverse effects. Chloramphenicol is an antibiotic which is considered to have a very narrow spectrum, with many organisms resistant to it, and carries the risk of aplastic anemia. It is vital that chloramphenicol be prescribed only when absolutely necessary, for example, treating strains of Haemophilus that are resistant to other antibiotics.
Vancomycin is a valuable antibiotic that should be used carefully. Wide or inappropriate use may lead to emergence of resistant strains. In addition, nephrotoxicity is likely to increase when systemic vancomycin is combined with gentamicin.
There is antagonism when tetracycline is used in combination with quinolone, erythromycin, and all the beta-lactam antibiotics. A beta-lactam antibiotic should not be used in combination with tetracyclines, erythromycin, or chloramphenicol; since the latter inhibit ribosomal function, they will interfere with the effects of beta-lactam antibiotics.
Azithromycin is a macrolide antibiotics belonging to the azalide group. It has been shown to be highly effective against chlamydial infections as well as against Gram-positive bacteria [31–33]. Azithromycin has a long elimination life reaching 68 h. Azithromycin has been found to be effective in the treatment of genital Chlamydia. A single, 1-g dose is sufficient to eradicate it. Azithromycin is also effective in the treatment of trachoma [34]. A 1-week course or repeated 3-day courses of azithromycin are required in chronic active cases of trachoma. The drug has high intracellular concentration in the macrophages and polymorphonuclear cells. Following a single oral dose of azithromycin, the drug remains in the conjunctiva above the minimum inhibitory concentration (MIC) of Chlamydia for up to 2 weeks [31]. The drug is currently available as eyedrops at a concentration of 1.5 % as Azyter® (Laboratoires Theá, Clermont-Ferrand, France) and 1.0 % concentration as Azasite (Inspire Pharmaceuticals Inc, NC, USA). The tear concentration of topical azithromycin was studied following topical administration of a single dose of azithromycin 1.0 and 1.5 % in healthy volunteers [32]. This study was a prospective, randomized double-masked study. A total of 91 healthy volunteers with normal tear functions were included. Twenty-three subjects received azithromycin 0.5 % eyedrops, 58 subjects received azithromycin 1.0 % eyedrops, and 38 subjects received azithromycin 1.5 % eyedrops. Tears were collected from each subject at seven time points over a 24-h period using the Schirmer strips that were weighed before and after tear sampling. The tear samples were analyzed for azithromycin by high-performance liquid chromatography mass spectrometry (HPLC-MS). The peak of azithromycin was noted 10 min after instillation and the mean concentration remained above 7 mg/l for 24 h. A late-onset increase in the tear concentration of azithromycin was noted at 8–12 h and may be explained by the known azithromycin release from the tissues after storage in the cells [31, 35, 36].
In another study, Kuehne and coworkers [33] measured the concentration of azithromycin and clarithromycin in rabbit corneal tissue following topical application of 2 mg/ml (0.2 %) of azithromycin and 10 mg/ml (0.1 %) of clarithromycin. It was shown that topical azithromycin concentrations were higher in the corneal tissue than clarithromycin. Azithromycin is used for the treatment of chlamydial conjunctivitis, trachoma, keratitis due to Mycobacterium chelonae, and chronic blepharitis [31, 36–38].Topical azithromycin is used for the treatment of blepharitis [36–38]. Corneas exposed to desiccation showed significant increase in the azithromycin tissue level compared to normal eyes following topical application of azithromycin 1.5 % eyedrops [39]. It appears that dryness may increase the tissue absorption of the cornea [39].
Linezolid (Zyvox®) is a synthetic antibiotic, is a member of the oxazolidinones used for the treatment of serious infections caused by Gram-positive bacteria [40]. Linezolid inhibits protein synthesis and appears to work by disrupting the translation of messenger RNA into proteins in the ribosomes. Linezolid binds to 50S subunit of the ribosome. It has been shown that linezolid is most active against Gram-positive bacteria including streptococci, vancomycin-resistant-enterococci, and methicillin-resistant-Staphylococcus aureus (MRSA). The main indications of linezolid are infections of the skin and soft tissues and pneumonia. The drug is available in the United States and the United Kingdom under the name of Zyvox® and in European countries under the name of Zyvoxid®. On the other hand, in Canada and Mexico, the drug is known as Zyvixam®. Generics of these drugs are available in India under the name of Linospan by Cipla.
Linezolid is an oxazolidinone antibiotic which is a protein synthesis inhibitor. Resistance to linezolid by bacteria has remained low. Linezolid has proven to be safe and effective in infections due to susceptible organisms. The US Food and Drug Association approved linezolid in April 2000. It is considered a bacteriostatic agent, and the main indication of linezolid is the treatment of severe infections caused by Gram-positive bacteria that are resistant to other antibiotics. It has a narrow spectrum and, therefore, remains a reserved antibiotic for cases with severe infections due to resistant bacteria. Linezolid has been associated with Clostridium difficile-associated diarrhea and pseudomembranous colitis. The long-term use of linezolid may lead to bone marrow suppression and thrombocytopenia.
2.6 Antibiotics That Inhibit Nucleic Acid Synthesis
The fourth group of antibiotics, the quinolones, comprises antibiotics which inhibit nucleic acid synthesis [5, 41–66].
Pyrimethamine interferes with the synthesis of the hydrofolate which is an important building block of bacterial DNA. The drug is used for the treatment of Toxoplasma. Rifamycin interferes with nucleic acid synthesis by the inhibition of RNA-dependent DNA polymerase. Sulfonamides are synergistic with trimethoprim and, have been combined for systemic use.
Fluoroquinolones have a fluorine substitution at position 6 of the quinolone molecule. Additional substitutions at position 1 and position 7 markedly affect antimicrobial efficacy as well as penetration. These alterations have substantially improved the antimicrobial effects against Gram-positive as well as Gram-negative organisms in addition to improving solubility in ophthalmic solutions. Norfloxacin was the first fluoroquinolone to be used topically for ocular infections. It has primarily Gram-negative activity, including antipseudomonal activity as well as limited Gram-positive activity.
The regulation of DNA supercoiling is essential to DNA transcription and replication. In supercoiling, the DNA molecule coils up and shortens the molecule. The DNA helix must unwind to permit the proper function of the enzymatic machinery involved in these processes. Topoisomerases serve to maintain both the transcription and replication of DNA. Type I and type II topoisomerases cut one strand or two strands of DNA, respectively.
The underlying mechanism of action is reversible trapping of DNA gyrase (topoisomerase II) and topoisomerase IV-DNA complexes. Complex formation is followed by reversible inhibition of DNA synthesis. As fluoroquinolone concentrations increase, cell death occurs as double-stranded DNA breaks releasing trapped gyrase and/or topoisomerase IV complexes. In many Gram-negative bacteria, resistance arises primarily from mutation of the gyrase A protein, while in some Gram-positive bacteria, primary resistance occurs via mutation in topoisomerase IV. In addition, efflux pumps that actively pump antibiotics out of the bacteria confer multidrug resistance via these membrane-associated efflux pumps. Gatifloxacin and moxifloxacin are more resistant to these efflux pumps. This change additionally confers added anaerobic activity. Gram-negative organisms may also exhibit decreased levels of outer membrane proteins that facilitate diffusion into the bacterial cell of drug, thereby conferring additional resistance, which can work in concert with the efflux pumps. These last two mechanisms confer a form of resistance and can be overwhelmed by higher concentrations of drug [65].
Fluoroquinolones include moxifloxacin, gatifloxacin, besifloxacin, ciprofloxacin, fleroxacin, lomefloxacin, norfloxacin, ofloxacin, perfloxacin, and temfloxacin, all of which are C-7 1-piperazinyl and C-7 fluoro-substituted quinolones. The drugs are more potent than the original nalidixic acid structure. Several quinolones are available in topical eyedrop form. These drugs have good in vitro actions against many Gram-negative and Gram-positive bacteria, while action against anaerobic bacteria remains poor. The mechanism of action of the quinolones is through inhibition of DNA gyrase. Lomefloxacin is effective against most Gram-negative and Gram-positive organisms. Studies on Chlamydia trachomatis show that this organism is moderately susceptible to lomefloxacin.
These susceptibilities are in contrast to the aminoglycosides and β-lactam antibiotics which have activity against bacterial cells in the growth phase, whereas fluoroquinolones are rapidly bactericidal in vitro and in vivo in both growth phase and secondary phase of cell growth.
Studies carried out on the rabbit model have revealed that lomefloxacin readily penetrates the cornea, iris, and ciliary body of the eye and reaches an appreciable concentration in the aqueous. Penetration occurs after both local and systemic administration and penetration have been shown to be increased in the presence of melanin.
The fluoroquinolones have two pKa values on each side of physiological pH with an isoelectric point at pH 7.4. Unionized fluoroquinolones are considered to be very lipophilic, a factor that is thought to influence considerably the mechanism by which these compounds penetrate bacterial cell membranes. Fluoroquinolones are approximately 20–30 % protein bound. This value has been found to be independent of the drug concentration. Following oral administration of lomefloxacin, 10 % of the drug is protein bound in the serum. Evidence from animal studies suggests that lomefloxacin is excreted unchanged by the kidney, although small concentrations of 5 metabolites have been described. The most notable drug interaction occurring is the effect of fluoroquinolones on the clearance of theophylline. Plasma concentrations of theophylline are raised by approximately 19 % during coadministration with perfloxacin as compared to 111 % for enoxacin and 23 % for ciprofloxacin. Ofloxacin and nalidixic acid do not increase the apparent plasma level of theophylline. The interaction is supposed to rise, not through the parent fluoroquinolone but through their 4-oxo metabolites. This interaction is produced through the effect on hepatic p450-related isoenzymes resulting in reduced capacity of N-demethylation of theophylline. No oxo-metabolite is produced in the metabolic elimination of lomefloxacin, and the drug is extensively excreted. Theophylline adjustment does not seem to be necessary in patients receiving concomitant lomefloxacin.
Quinolones are interesting in ophthalmology because several of them are available in topical forms. Levofloxacin, lomefloxacin, ciprofloxacin, ofloxacin, norfloxacin, moxifloxacin, gatifloxacin, besifloxacin, and temefloxacin are available for topical use. They are effective against Gram-negative organisms, and in topical form ciprofloxacin has a useful role in the treatment of bacterial keratitis caused by Pseudomonas. Certain fourth-generation quinolones, however, have limited efficacy against Gram-positive cocci.
Quinolones are highly effective against Gram-negative organisms and have intermediate activity against staphylococci. They are effective against group B streptococci but not useful against group A streptococci, Streptococcus pneumonia, and anaerobes. Clearly, these antibiotics have selective effects against microorganisms, making them unsuitable for “blind shot blanket” therapy. In addition, systemic fluoroquinolones may cause cartilage erosion in children. They should not be used in children or pregnant women. As the case with tetracyclines, antacids may decrease absorption of oral quinolones.
The antibiotics of choice for common ocular pathogens are shown in Table 2.9. The compounding dosages for intravitreal injections of antimicrobial agents are shown in Table 2.10. The antimicrobial therapy for tuberculosis (Table 2.11) and for ocular toxoplasmosis is also listed (Table 2.12).
Compliance with Ethical Requirements Conflict of Interest The author declares that he has no conflict of interest. Informed Consent No human studies were carried out by the authors for this article. Animal Studies No animal studies were carried out by the authors for this article.
References
Karlowsky JA, Thornsberry C, Jones ME, Evangelista AT, Critchley IA, Sahm DF. TRUST surveillance program. Factors associated with relative rates of antimicrobial resistance among streptococcus pneumoniae in the United States: Results from the TRUST Surveillance Program 1998–2002. Clin Infect Dis. 2003;36(8):963–70.
Alfonso E, Crider J. Ophthalmic infections and their anti-infective challenges. Surv Ophthalmol. 2005;50 Suppl 1:S1–6.
Tabbara KF. The new era of infections [editorial]. Arch Soc Esp Oftalmol. 1996;70:527–8.
Tabbara KF. Antibiotics in ophthalmology [editorial]. Saudi J Ophthalmol. 1999;13(1):1–2.
Ayaki M, Iwasawa A, Niwano Y. In vitro assessment of the cytotoxicity of six topical antibiotics to four cultured ocular surface cell lines. Biocontrol Sci. 2012;17(2):93–9.
Hong J, Chen J, Sun X, Deng SX, Chen L, Cao W, Yu X, Xu J. Pediatric bacterial keratitis cases in Shanghai: microbiological profile, antibiotic susceptibility and visual outcome. Eye (Lond). 2012;26(12):1571–8. doi:10.1038/eye.2012.210.
Barreau G, Mounier M, Marin B, Adenis JP, Robert PY. Intracameral cefuroxime injection at the end of cataract surgery to reduce the incidence of endophthalmitis: French study. J Cataract Refract Surg. 2012;38(8):1370–5.
Robert MC, Moussally K, Harissi-Dagher M. Review of endophthalmitis following Boston Keratoprosthesis type 1. Br J Ophthalmol. 2012;96(6):776–80.
Cheung CS, Wong AW, Lui A, Kertes PJ, Devenyi RG, Lam WC. Incidence of endophthalmitis and use of antibiotic prophylaxis after intravitreal injections. Ophthalmology. 2012;119(8):1609–14.
Mathias MT, Horsley MB, Mawn LA, Laquis SJ, Cahill KV, Foster J, Amato MM, Durairaj VD. Atypical presentations of orbital cellulitis caused by methicillin-resistant Staphylococcus aureus. Ophthalmology. 2012;119(6):1238–43.
Scott WJ, Eck CD. Povidone-iodine and ophthalmia neonatorum. Ophthalmology. 2012;119(3):653–4; author reply 654.
Emmett Hurley P, Harris GJ. Subperiosteal abscess of the orbit: duration of intravenous antibiotic therapy in nonsurgical cases. Ophthal Plast Reconstr Surg. 2012;28(1):22–6.
Gupta M, Durand ML, Sobrin L. Vancomycin resistance in ocular infections. Int Ophthalmol Clin. 2011;51(4):167–81. Review.
Yiu G, Young L, Gilmore M, Chodosh J. Prophylaxis against postoperative endophthalmitis in cataract surgery. Int Ophthalmol Clin. 2011;51(4):67–83. Review.
Mataftsi A, Tsinopoulos IT, Tsaousis KT, Dimitrakos SA. Perioperative antibiotic prophylaxis during cataract surgery in Greece. J Cataract Refract Surg. 2011;37(9):1732–3.
Jayahar BM, Ramakrishnan R, Ramesh S, Murugan N. Extended-spectrum beta-lactamase resistance among bacterial isolates recovered from ocular infections. Ophthalmic Res. 2012;47(1):52–6.
Burton MJ, Pithuwa J, Okello E, Afwamba I, Onyango JJ, Oates F, Chevallier C, Hall AB. Microbial keratitis in East Africa: why are the outcomes so poor? Ophthalmic Epidemiol. 2011;18(4):158–63.
Hadatsch B, Butz D, Schmiederer T, Steudle J, Wohlleben W, Süssmuth R, Stegmann E. The biosynthesis of teicoplanin-type glycopeptide antibiotics: assignment of p450 mono-oxygenases to side chain cyclizations of glycopeptide a47934. Chem Biol. 2007;14(9):1078–89.
Ho JY, Huang YT, Wu CJ, Li YS, Tsai MD, Li TL. Glycopeptide biosynthesis: Dbv21/Orf2 from dbv/tcp gene clusters are N-Ac-Glm teicoplanin pseudoaglycone deacetylases and Orf15 from cep gene cluster is a Glc-1-P thymidyltransferase. J Am Chem Soc. 2006;128(42):13694–5.
de Lalla F, Nicolin R, Rinaldi E, Scarpellini P, Rigoli R, Manfrin V, Tramarin A. Prospective study of oral Teicoplanin versus oral vancomycin for therapy of pseudomembranous colitis and Clostridium difficile associated diarrhea. Antimicrob Agents Chemother. 1992;36:2192–6.
Molina JM, Tourneur M, Sarfati C, Chevret S, de Gouvello A, Gobert JG, Balkan S, Derouin F, Agence Nationale de Recherches sur le SIDA 090 Study Group. Fumagillin treatment of intestinal microsporidiosis. N Engl J Med. 2002;346(25):1963–9.
Tabbara KF, Hyndiuk RA, editors. Infections of the eye. Boston: Little, Brown and Company Publishers; 1996.
Tabbara KF, Al-Jabarti A. Hospital construction-associated outbreak of ocular aspergillosis after cataract surgery. Ophthalmology. 1998;105(3):522–6.
Parchand S, Gupta A, Ram J, Gupta N, Chakrabarty A. Voriconazole for fungal corneal ulcers. Ophthalmology. 2012;119(5):1083.
Prokosch V, Gatzioufas Z, Thanos S, Stupp T. Microbiological findings and predisposing risk factors in corneal ulcers. Graefes Arch Clin Exp Ophthalmol. 2012;250(3):369–74.
Oldenburg CE, Acharya NR, Tu EY, Zegans ME, Mannis MJ, Gaynor BD, Whitcher JP, Lietman TM, Keenan JD. Practice patterns and opinions in the treatment of acanthamoeba keratitis. Cornea. 2011;30(12):1363–8.
Sakarya R, Sakarya Y, Ozcimen M, Kesli R, Alpfidan I, Kara SJ. Ocular penetration of topically applied 1% daptomycin in a rabbit model. J Ocul Pharmacol Ther. 2013;29(1):75–8. doi:10.1089/jop.2012.0111.
Comer GM, Miller JB, Schneider EW, Khan NW, Reed DM, Elner VM, Zacks DN. Intravitreal daptomycin: a safety and efficacy study. Retina. 2011;31(6):1199–206.
Tabbara KF, Antonios S, Alvarez H. Effects of fusidic acid on staphylococcal keratitis. Br J Ophthalmol. 1989;73(2):136–9.
Taylor PB, Burd EM, Tabbara KF. Corneal and intraocular penetration of topical and subconjunctival fusidic acid. Br J Ophthalmol. 1987;1(8):598–601.
Tabbara KF, Al Kharashi SA, Al-Mansouri SM, Al-Omar OM, Cooper H, Abu El-Asrar AM, Foulds G. Ocular levels of azithromycin. Arch Ophthalmol. 1998;116:1625–8.
Chiambaretta F, Garraffo R, Elena PP, Pouliquen P, Delval L, Rigal D, Dubray C, Goldschmidt P, Tabbara K, Cochereau I. Tear concentrations of azithromycin following topical administration of a single dose of azithromycin 0.5%, 1.0%, and 1.5% eyedrops (T1225) in healthy volunteers. Eur J Ophthalmol. 2008;18(1):13–20.
Kuehne JJ, Yu AL, Holland GN, et al. Corneal pharmacokinetics of topically applied azithromycin and clarithromycin. Am J Ophthalmol. 2004;138(4):547–53.
Tabbara KF, Abu El-Asrar AM, Al-Omar OM, Choudhury AH, Al-Faisal ZK. Single-dose Azithromycin in the treatment of trachoma: a randomized, controlled study. Ophthalmology. 1996;103(5):842–6.
Abshire R, Cockrum P, Crider J, Schlech B. Topical antibacterial therapy for mycobacterial keratitis: potential for surgical prophylaxis and treatment. Clin Ther. 2004;26(2):191–6.
Luchs J. Efficacy of tropical azithromycin ophthalmic solution 1% in the treatment of posterior blepharitis. Adv Ther. 2008;25(9):855–70.
Igami TZ, Holzchuh R, Osaki TH, Santo RM, Kara-Jose N, Hida RY. Oral azithromycin for treatment of posterior blepharitis. Cornea. 2011;30(10):1145–9.
Veldman P, Colby K. Current evidence for topical azithromycin 1% ophthalmic solution in the treatment of blepharitis and blepharitis-associated ocular dryness. Int Ophthalmol Clin. 2011;51(4):43–52. Review.
Tabbara KF, Kotb AK, Hammouda EF, Elkum N. Effects of dehydration on corneal tissue absorption of topical azithromycin in rabbits. Curr Eye Res. 2005;30:915–8.
Tascini C, Gemignani G, Doria R, Biancofiore G, Urbani L, Mosca C, Malacarne P, Papineschi F, Passaglia C, Dal Canto L, Procaccini M, Furneri G, Didoni G, Filipponi F, Menichetti F. Linezolid treatment for gram positive infections: a retrospective comparison with teicoplanin. J Chemother. 2009;21(3):311–6.
Blondeau JM. Fluoroquinolones: mechanism of action, classification, and development of resistance. Surv Ophthalmol. 2004;49 Suppl 2:S73–8.
Tabbara KF, El-Sheikh HF, Islam SMM, Hammouda E. Treatment of acute bacterial conjunctivitis with topical Lomefloxacin 0.3% compared to topical Ofloxacin 0.3%. Eur J Ophthalmol. 1999;4(4):269–75.
Alexandrakis G, Alfonso EC, Miller D. Shifting trends in bacterial keratitis in South Florida and emerging resistance to fluoroquinolones. Ophthalmology. 2000;107:1497–502.
Chaudhry NA, Flynn Jr HW, Murray TG, Tabandeh H, Mello Jr MO, Miller D. Emerging ciprofloxacin-resistant Pseudomonas aeruginosa. Am J Ophthalmol. 1999;128(4):509–10.
Goldstein MH, Kowalski RP, Gordon YJ. Emerging fluoroquinolone resistance in bacterial keratitis: a 5-year review. Ophthalmology. 1999;106:131–8.
Aliprandis E, Ciralsky J, Lai H, Herling I, Katz HR. Comparative efficacy of topical moxifloxacin versus ciprofloxacin and vancomycin in the treatment of P. aeruginosa and ciprofloxacin-resistant MRSA keratitis in rabbits. Cornea. 2005;24(2):201–5.
Caballero AR, Marquart ME, O’Callaghan RJ, Thibodeaux BA, Johnston KH, Dajcs JJ. Effectiveness of fluoroquinolones against Mycobacterium abscessus in vivo. Curr Eye Res. 2006;31(1):23–9.
Callegan MC, Ramirez R, Kane ST, Cochran DC, Jensen H. Antibacterial activity of the fourth-generation fluoroquinolones gatifloxacin and moxifloxacin against ocular pathogens. Adv Ther. 2003;20(5):246–52.
Dajcs JJ, Thibodeaux BA, Marquart ME, Girgis DO, Traidej M, O’Callaghan RJ. Effectiveness of ciprofloxacin, levofloxacin or moxifloxacin for treatment of experimental Staphylococcus aureus keratitis. Antimicrob Agents Chemother. 2004;48(6):1948–52.
El-Sheikh HF, Tabbara KF, Islam SMM, Hammouda E. Susceptibility of clinically significant ocular isolates to Lomefloxacin 0.3%. Saudi J Ophthalmol. 1999;13(1):31–6.
Herrygers LA, Noecker RJ, Lane LC, Levine JM. Comparison of corneal surface effects of gatifloxacin and moxifloxacin using intensive and prolonged dosing protocols. Cornea. 2005;24(1):66–71.
Hofling-Lima AL, de Freitas D, Sampaio JL, Leao SC, Contarini P. In vitro activity of fluoroquinolones against Mycobacterium abscessus and Mycobacterium chelonae causing infectious keratitis after LASIK in Brazil. Cornea. 2005;24(6):730–4.
Lee SB, Oliver KM, Strube YN, Mohan SK, Slomovic AR. Fourth-generation fluoroquinolones in the treatment of mycobacterial infectious keratitis after laser-assisted in situ keratomileusis surgery. Can J Ophthalmol. 2005;40(6):750–3.
Levine JM, Noecker RJ, Lane LC, Herrygers L, Nix D, Snyder RW. Comparative penetration of moxifloxacin and gatifloxacin in rabbit aqueous humor after topical dosing. J Cataract Refract Surg. 2004;30(10):2177–82.
Moshirfar M, Mirzaian G, Feiz V, Kang PC. Fourth-generation fluoroquinolone-resistant bacterial keratitis after refractive surgery. J Cataract Refract Surg. 2006;32(3):515–8.
Patel NR, Reidy JJ, Gonzalez-Fernandez F. Nocardia keratitis after laser in situ keratomileusis: clinicopathologic correlation. J Cataract Refract Surg. 2005;31(10):2012–5.
Price MO, Price Jr FW, Maclellan D. Effect of gatifloxacin 0.3% and moxifloxacin 0.5% ophthalmic solutions on human corneal epithelium following 2 dosing regimens. J Cataract Refract Surg. 2005;31(11):2137–41.
Rhee MK, Kowalski RP, Romanowski EG, Mah FS, Ritterband DC, Gordon YJ. A laboratory evaluation of antibiotic therapy for ciprofloxacin-resistant Pseudomonas aeruginosa. Am J Ophthalmol. 2004;138(2):226–30.
Robertson SM, Curtis MA, Schlech BA, Rusinko A, Owen GR, Dembinska O, Liao J, Dahlin DC. Ocular pharmacokinetics of moxifloxacin after topical treatment of animals and humans. Surv Ophthalmol. 2005;50 Suppl 1:S32–45.
Tabbara KF, Cooper H, Shareef AH. Decrease in tear bioavailability of ciprofloxacin in eyes with carbon containing eyeliners. Saudi Med J. 1999;20(9):717–8.
Thibodeaux RA, Dajcs JJ, Caballero AR, Marquart ME, Girgis DO, O’Callaghan RJ. Quantitative comparison of fluoroquinolone therapies of experimental gram-negative bacterial keratitis. Curr Eye Res. 2004;28(5):337–42.
Malhotra R, Gira J, Berdy GJ, Brusatti R. Safety of besifloxacin ophthalmic suspension 0.6% as a prophylactic antibiotic following routine cataract surgery: results of a prospective, parallel-group, investigator-masked study. Clin Ophthalmol. 2012;6:855–63.
Fukuda M, Yamada M, Kinoshita S, Inatomi T, Ohashi Y, Uno T, Shimazaki J, Satake Y, Maeda N, Hori Y, Nishida K, Kubota A, Nakazawa T, Shimomura Y. Comparison of corneal and aqueous humor penetration of moxifloxacin, gatifloxacin and levofloxacin during keratoplasty. Adv Ther. 2012;29(4):339–49.
Miyake T, Ito N, Tajima K, Goto H, Furukawa T. Comparison of moxifloxacin and levofloxacin in an epithelial disorder model using cultured rabbit corneal epithelial cell sheets. Graefes Arch Clin Exp Ophthalmol. 2012;250(7):1035–41.
Shalchi Z, Gurbaxani A, Baker M, Nash J. Antibiotic resistance in microbial keratitis: ten-year experience of corneal scrapes in the United Kingdom. Ophthalmology. 2011;118(11):2161–5.
Cervantes LJ, Mah FS. Clinical use of gatifloxacin ophthalmic solution for treatment of bacterial conjunctivitis. Clin Ophthalmol. 2011;5:495–502.
Tabbara KF. Tuberculosis. Curr Opin Ophthalmol. 2007;18(6):493–501.
Tabbara KF. Ocular toxoplasmosis. In: Tasman W, Jaeger EA, editors. Duane’s clinical ophthalmology, vol. Uvea section. Baltimore: Lippincott Williams & Wilkins; 2008.
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Tabbara, K.F. (2014). Antimicrobial Agents in Ophthalmology. In: Tabbara, K., El-Asrar, A., Khairallah, M. (eds) Ocular Infections. Essentials in Ophthalmology. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-43981-4_2
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