Problems associated with potential massive use of antimicrobial agents as prophylaxis or therapy of a bioterrorist attack E. Navas

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REVIEW Problems associated with potential massive use of antimicrobial agents as prophylaxis or therapy of a bioterrorist attack E. Navas Servicio de Enfermedades Infecciosas, Hospital Ramón y Cajal, Madrid, Spain In addition to the direct sanitary damage of a terrorist attack caused by biological weapons, the consequences of the massive stockpiling and consumption of antimicrobial agents in order to treat or prevent the disease under a potential epidemic due to pathogenic bacteria must also be considered. Bacillus anthracis, Francisella tularensis and Yersinia pestis are the bacteria most likely to be used as terrorist weapons. Tetracyclines, quinolones and aminoglycoside are the antibiotics of choice against these microorganisms. The recent terrorist attack with anthrax spores in the USA caused a substantial increase in the sales of ciprofloxacin, as thousands of citizens received antibiotic prophylaxis for either confirmed or suspected exposure to anthrax, and many others stockpiled antibiotic supplies at their homes under a panic scenario. The massive consumption of antimicrobial drugs may lead to the selection of antibiotic resistant strains, and to the appearance of undesirable side effects, such as anaphylaxis or teratogenesis. National health authorities must develop realistic protocols in order to detect, treat and prevent mass casualties caused by biological weapons. An antibiotic stockpile has to be planned and implemented, and home stockpiling of antibiotics must be strongly discouraged. Keywords Bioterrorism, Ciprofloxacin, Doxycycline, Antibiotics, Drug resistance Clin Microbiol Infect 2002; 8: 534 539 Biological terrorism has unique characteristics that make it different from other kinds of war. The reaction of the population to conventional terrorist attacks (e.g. bombs) is unfortunately well known and, to some extent, predictable. Such attacks are readily detected by the authorities, and the injured receive immediate medical care. The consequences of a massive attack with a biological weapon may be dramatically different. The release of microorganisms or their toxins is silent, and detection of the epidemic is not possible until significant numbers of people with the disease are assisted at medical facilities; moreover, the affected patients may be farfromthegeographiclocationwherethe biological weapon hasbeen used,andthe agent mayhave been disseminated in different locations. As time passes, transmission of the agent may cause the appearance of secondary cases, confusing the situation even Corresponding author and reprint requests: E. Navas, Servicio de Enfermedades Infecciosas, Hospital Ramón y Cajal, Carretera de Colmenar Km 9,100, 28034 Madrid, Spain E-mail: enrique.navas@eurociber.es more. The initial consequences of the attack will depend on the infectivity, virulence, lethality and contagiousness of the infective agent. Infection control measures will be decisive in limiting the outbreak, and they begin with communication of the risks to the population in order to avoid panic reactions. Prompt implementation of quarantine precautions and administration of vaccines and antimicrobials to the exposed population are essential in avoiding further spread of the disease [1,2]. In a theoretical situation, once the attack is detected, and a first estimation of the magnitude of the disease has been made, coordination of the public health resources is mandatory, and evaluation of the availability of hospitals and clinics, staff and pharmaceutical products is a basic step in the design of the emergency plan. In a conventional terrorist event, there is no doubt which people are injured by the weapons. In a bioterrorist attack, however, unaffected civilians may overwhelm the medical facilities because of panic, minor symptoms due to coincidental diseases, or fear that they are suffering from the disease. In this situation, ß 2002 Copyright by the European Society of Clinical Microbiology and Infectious Diseases

Navas Antimicrobial agents as prophylaxis or therapy of a bioterrorist attack 535 Table 1 Recommendations for antimicrobial therapy following bioterrorist bacterial attacks (Working Group on Civilian Biodefense) Treatment Post-exposure prophylaxis Anthrax Ciprofloxacin for 60 days Ciprofloxacin for 60 days Penicillin G for 60 days Amoxicillin for 60 days Doxycycline for 60 days Doxycycline for 60 days Yersinia pestis Streptomycin for 10 days Doxycycline for 7 days Gentamicin for 10 days Ciprofloxacin for 7 days Doxycycline for 10 days Chloramphenicol for 7 days Chloramphenicol for 10 days Ciprofloxacin for 10 days Francisella tularensis Streptomycin for 10 days Doxycycline for 14 days Gentamicin for 10 days Ciprofloxacin for 14 days Doxycycline for 14 21 days Chloramphenicol for 14 21 days Ciprofloxacin for 10 days massive personal stockpiling and consumption of antibiotics to prevent the disease may have incalculable consequences [3]. Among the potential biological weapons, category A agents are those most likely to cause mass casualties, because of their infectivity and virulence. This category includes three pathogenic bacteria that have the highest potential for use in large-scale bioterrorist attacks: Bacillus anthracis, Francisella tularensis and Yersinia pestis [4]. The antibiotics of choice in the treatment and prevention of these agents, according to the Working Group on Civilian Biodefense, are summarized in Table 1 [5 7]. Doxycycline, fluoroquinolones and streptomycin are the antibiotics that must be considered in the prevention and treatment of these conditions. Other bacteria that could be used as weapons, such as Coxiella burnetti, Brucella spp., Burkholderia mallei, Vibrio cholerae, Salmonella spp., Shigella dysenteriae or Escherichia coli 0157:H7, are less likely to be disseminated widely, have less lethality, and are therefore placed in category B [4]. In the case of exposure to Bacillus anthracis spores, 60 days of an antibiotic regimen that includes either doxycycline or a quinolone is recommended. The delayed transformation of the inhaled spores to vegetative bacteria explains why the antibiotic regimen must be extended up to 60 days after exposure [5,8]. Recent experience in the USA was that no patient exposed to anthrax spores receiving antibiotic prophylaxis developed the disease [9]. Scientific evidence on the efficacy of antimicrobial prevention of tularemia and plague is scarce. For tularemia, streptomycin is the most active antibiotic, and, to date, most authorities have recommended preemptive streptomycin (gentamicin can be used instead) as first choice after accidental laboratory exposure to this agent [10]. The aminoglycoside antibiotics have to be given parenterally, are ototoxic and nephrotoxic, and so seem to be unsuitable for mass prophylaxis. Although the efficacy of ciprofloxacin and doxycycline in humans for an aerosol challenge of F. tularensis is unknown, an experimental mouse model indicates that, when initiated early, they may be effective as post-exposure prophylaxis [11]. In the case of plague, streptomycin is the most active drug, and is the antibiotic of choice in the treatment of severe cases [12,13]. Doxycycline is preferred for prophylaxis, although ciprofloxacin, chloramphenicol and co-trimoxazole may also be effective [14,15]. The required duration of prophylaxis against Y. pestis and F. tularensis is unknown; because they are not spore-forming bacteria, a short course (7 14 days) should be enough for most attacks. Pneumonic plague is capable of being transmitted by inhalation from person to person; in a situation in which an established epidemic makes human-to-human transmission possible, besides quarantine and barrier measures [16], antimicrobial prophylaxis may well have to be prolonged. In summary, inordertobepreparedforapotential bacterial attack due to any of these three species, governments should guarantee a sufficient supply of tetracyclines, quinolones and streptomycin. The authorities must, however, keep in mind that the threat of attack with antibiotic-resistant microorganisms may make this antibiotic choice completely useless; the recent isolation of a Y. pestis strain with plasmid-mediated multiresistance in Madagascar

536 Clinical Microbiology and Infection, Volume 8 Number 8, 2002 [17,18] is worrisome, and introduction of resistance and virulence genes into these pathogenic bacteria through bioengineering may well be achieved by military or terrorist-allied laboratories. PREPAREDNESS AGAINST BIOLOGICAL TERRORISM: THE ANTIBIOTIC STOCKPILE Public-health plans, in order to be prepared against the release of any of the previously mentioned microbiological weapons, must, of course, include an estimate of the types and quantities of vaccines and antibiotics that must be stockpiled by the health authorities. This is not, however, an easy task, as the dynamics of transmission of these diseases in an artificial setting caused by the intentional spread of the infectious agent through terrorist action may be very different from what we know about the biology of the microorganisms in the natural environment. In 1970, the World Health Organization estimated that the aerial release of 50 kg of anthrax spores over a population area of five million people would harm 250 000, and that 100 000 people would be expected to die without treatment; 50 kg of F. tularensis in a similar area would cause disease in 250 000, and 19 000 deaths, and 50 kg of Y. pestis would cause 150 000 cases of pneumonic plague and 36 000 deaths [19]. Although the scientific basis of these estimates has not been clearly described in the literature, the assumption may not be unreasonable, as was shown by the consequences of the accidental leak of anthrax from a military facility in Sverdlovsk, in the former USSR [20]; this unintentional release of a non-specified quantity of Bacillus anthracis spores was responsible for at least 64 human deaths. How feasible it is to obtain large quantities of anthrax spores or other pathogens in some kind of dry powder suitable for massive aerosolization is something that only military researchers or bioterrorist scientists can determine. If the menace of an airborne massive attack with virulent F. tularensis, Y. pestis or Bacillus anthracis is real, the threatened governments should stockpile millions of doses of tetracyclines and fluoroquinolones. The list of potential biological agents is so large that it is impossible to keep large stocks of every vaccine, antiserum or antibacterial to off-set every agent that may be used in a biological attack. The pharmaceutical companies should also be queried about their capacity to manufacture the drugs upon demand. The recent US experience with the terrorist attacks using anthrax spores sent through the mail is particularly helpful as a guide on how to approach future bioterrorist events. As of 14 November, the Centers for Disease Control (CDC) reported 22 anthrax cases in several districts (Columbia, Florida, New Jersey, New York City) and five fatalities due to inhalation disease. Most cases occurred among persons with known or suspected contact with opened letters contaminated with Bacillus anthracis spores [9]. Approximately 32 000 people initiated antimicrobial prophylaxis following potential exposure to Bacillus anthracis at workplaces in the affected districts, and approximately 7500 specimens were sent for Bacillus anthracis testing [21]. It is obvious that thousands of other citizens might have received antibiotic prophylaxis without the CDC s knowledge, and that many others might have stockpiled ciprofloxacin at home. The sales of ciprofloxacin in the USA increased by 12% during the period of the anthrax attack, in comparison with the preceding year. The possibility of a large-scale attack caused a patent dispute between the US and Canadian governments and Bayer, the manufacturer of ciprofloxacin. The US government authorities calculated a need for antibiotics for ten million persons. For a 60- daysupply, Bayer scapacitytomanufacture enough ciprofloxacin was clearly insufficient. Several generic companies received Food and Drug Administration (FDA) clearance under a special legal framework, the rule 28 USC 1498, so that they could be asked to manufacture the drug for the government without a license from Bayer. THE THREAT OF ANTIBIOTIC RESISTANCE The link between antibiotic use and the development of resistance has been well known since the discovery of penicillin more than 50 years ago [22]. Obviously, one of the dangers of the widespread use of antibiotics for the prevention or treatment of infections due to biological weapons is the selection and community spread of resistant bacteria. The use of antimicrobial agents in food animals for growth promotion is an excellent, although unfortunate, experimental model of selection of resistant strains, and explains the high rate of antimicrobial resistance in Salmonella and Campylobacter strains isolated from human sources [23]. In the case of the quinolones, resistance in E. coli

Navas Antimicrobial agents as prophylaxis or therapy of a bioterrorist attack 537 has increased in many countries in the last decade, in close relation to the rising use of this antibiotic in the treatment of urinary tract infections and as prophylaxis in neutropenic and cirrhotic patients [24]. The use of trimethoprim sulfamethoxazole in AIDS patients as prophylaxis against Pneumocystis carinii pneumonia has also been linked to the development of resistance; in a report from San Francisco General Hospital, resistance of E. coli isolated from HIV patients increased from 24% in 1988 to 74% in 1995 [25]. In a scenario of indiscriminate use of fluoroquinolones, not only is the selection of resistant strains among Gram-negative bacteria worrisome, but also, the dissemination of quinolone-resistant Streptococcus pneumoniae in the community may compromise therapeutic options in the treatment of respiratory infections in areas with high endemicity of penicillin-resistant pneumococci. In the last 5 years, several publications from different countries have reported an increasing prevalence of fluoroquinolone resistance in S. pneumoniae, in parallel with prescriptions of this group of antibiotics [26 28]. In a survey of S. pneumoniae isolates collected during the year 2000 in Hong Kong, the prevalence of fluoroquinolone resistance (levofloxacin MIC 4 mg/l) was 13.3%. Fluoroquinolone resistance was associated with old age and chronic obstructive pulmonary disease, and a history of previous quinolone therapy was common among the people harboring resistant strains [29]. In a recent Spanish survey, no strains of S. pneumoniae with an MIC for ciprofloxacin 4 mg/l were found among 125 pneumococcal strains isolated from children; on the contrary, 59 of 988 (6%) strains from adults were resistant. As children are seldom treated with fluoroquinolones, this finding suggests a link between fluoroquinolone consumption and development of resistance [30]. Undoubtedly, although the development of reduced susceptibility to fluoroquinolones in S. pneumoniae requires sequential mutations in the antibiotic target, massive consumption of fluoroquinolones as a result of a bioterrorist attack may definitely contribute to a significant increase in the prevalence of quinoloneresistant bacteria in the affected areas. The tetracyclines inhibit protein synthesis by reversible binding on the 30S ribosome. Effluxbased mechanisms are the principal means of resistance to the tetracyclines, and most frequently they are plasmid encoded. The tetracyclines are the drugs of choice for rickettsiae, chlamydiae, borreliae, and brucellae [31]. Although antibiotic treatment may contribute to the selection and spread of tetracycline-resistant bacteria, at the present time few strains of Pneumococcus, Staphylococcus and Gram-negative bacilli are susceptible to the tetracyclines, and therefore they are not firstchoice agents for the treatment of infections due to these microorganisms. The ecological effect of the use of doxycycline for mass prophylaxis may therefore not have long-term adverse therapeutic consequences. Personal stockpiling of antibiotics must always be discouraged, even in the face of a bioterrorist threat. If people accumulate antibiotics at home, and the anticipated exposure does not take place, it is probable that they will later misuse the stocked antibiotics for the treatment of other medical conditions, such as self-limited viral infections or uncomplicated bacterial infections. ANTIBIOTIC TOXICITY Antibiotic recommendations in a mass casualty setting must be carefully devised, in order to avoid agents with potential life-threatening secondary effects, such as severe hypersensitivity reactions or anaphylaxis, fulminant hepatitis, or exfoliative skin rash [32]. The teratogenic potential of the drugs must also be considered in this circumstance, as women of childbearing age may be treated in the first weeks of conception without knowledge of being pregnant. In any case, the therapeutic decisions must find a balance between the toxicity of the drugs against the benefits of preventive therapy for a potentially lethal infection. The toxicity profiles of the quinolones and of doxycycline are summarized in Table 2. The postmarketing studies of the newer quinolones (temafloxacin, grepafloxacin, trovafloxacin) identified severe adverse effects such as anaphylactoid reactions, hemolytic anemia, QT-interval prolongation and liver necrosis [33]. The older quinolones ciprofloxacin, ofloxacin and levofloxacin have not been associated with these adverse events, except for anecdotal anaphylactoid reactions due to ciprofloxacin reported in the literature [34]. Fluoroquinolones are not recommended for women during pregnancy, lactation or for young children, because of concerns about teratogenesis and cartilage toxicity. Animal models using high doses of ciprofloxacin, and surveys of mothers exposed to

538 Clinical Microbiology and Infection, Volume 8 Number 8, 2002 Table 2 Adverse effects attributed to fluoroquinolones and tetracyclines Fluoroquinolones Doxycycline Gastrointestinal (anorexia, nausea, bloating, abdominal pain) Central nervous system (dizziness, headache) Allergic and skin reactions Diarrhea (including Clostridium difficile colitis) Phototoxicity Arthropathy and tendinitis QTc prolongation Laboratory abnormalities (leukopenia, eosinophilia, elevated transaminases) Gastrointestinal intolerance Allergic and skin reactions Photosensitivity Central nervous system (dizziness, headache) Dental discoloration Esophageal ulcerations Diarrhea (including Clostridium difficile colitis) Hepatotoxicity Pancreatitis Benign intracranial hypertension ciprofloxacin during pregnancy, have not shown that ciprofloxacin causes maternal toxicity, embryotoxicity, or teratogenic effects. Quinolones have been reported to cause arthropathy in immature animals of various species[35,36]. Fluoroquinolones have been used successfully as second-line therapy in children with severe or multiresistant infections, although causing reversible arthropathy in some children with cystic fibrosis. Doxycycline is the preferred tetracycline, because of its activity, safety profile and pharmacokinetic properties. Hypersensitivity reactions are rare, and photosensitivity is less frequent with doxycycline than with other tetracyclines. Liver toxicity has been described, especially in patients receiving intravenous tetracyclines; pregnant patients are particularly susceptible to liver disease. Doxycycline-induced liver disease is exceptional. Pancreatitis has also been linked to tetracycline treatment. Tetracyclines are also contraindicatedin pregnant patients and in young children, because of dental staining, enamel hypoplasia, and inhibition of skeletal growth in the fetus. The Hungarian Congenital Abnormality Registry failed to detect any teratogenic risk in a case control study of 32 804 pregnant women, 63 of them treated with doxycycline [37]. Doxycycline undergoes less binding to calcium than do other tetracyclines, and may cause dental changes less frequently in children. Streptomycin and gentamicin are aminoglycoside antibiotics that have to be administered parenterally; they may cause irreversible cochlear and vestibular damage. Hypersensitivity reactions are uncommon. In the context of a bioterrorist attack setting, they should be reserved for the therapy of patients with severe plague or tularemia. Oral agents are better choices for large-scale post-exposure prophylaxis. CONCLUSION Biological terrorism should no longer be considered as a hypothetical danger; the threat is real, and public-health systems must be prepared for a rapid and efficacious response. In the case of bacterial biological weapons, B. anthracis, F. tularensis and Y. pestis are most likely to be implicated. Governments must endorse national plans for the detection, treatment and prevention of mass casualties due to these organisms. National stockpiles of doxycycline, fluoroquinolones and aminoglycosides are needed, and pharmaceutical manufacturers must be ready to produce sufficient quantitities of antimicrobials in the event of a massive bioterrorist attack. Personal stockpiling should be discouraged, in order to avoid misuse and shortage of antibiotics. The massive use of antimicrobials in this setting may eventually lead to an increase in the prevalence of resistant bacteria in the community. Recommendations and guidelines for the treatment and prevention of infections due to biological weapons must also take into account the cost, effectiveness and sideeffects of the selected vaccines and antimicrobials. REFERENCES 1. Anon. Biological and chemical terrorism: strategic plan for preparedness and response. Recommendations of the CDC strategic planning workgroup. MMWR Morb Mortal Wkly Rep 2000; 49(RR-4): 1 14. 2. Barbera J, Macintyre A, Gostin L et al. Large-scale quarantine following biological terrorism in the United States: scientific examination, logistic and legal limits, and possible consequences. JAMA 2001; 286: 2711 17. 3. Inglesby TV. Anthrax: a possible case history. Emerg Infect Dis 1999; 5: 556 60.

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