Antimicrobial use and antimicrobial resistance: a population perspective. (Perspectives).The need to stem the growing problem of antimicrobial resistance has prompted multiple, sometimes conflicting, calls for changes in the use of antimicrobial agents Antimicrobial agents Chemical compounds biosynthetically or synthetically produced which either destroy or usefully suppress the growth or metabolism of a variety of microscopic or submicroscopic forms of life. . One source of disagreement concerns the major mechanisms by which antibiotics select resistant strains. For infections like tuberculosis, in which resistance can emerge in treated hosts through mutation, prevention of antimicrobial resistance in individual hosts is a primary method of preventing the spread of resistant organisms in the community. By contrast, for many other important resistant pathogens, such as penicillin-resistant Streptococcus pneumoniae Streptococcus pneu·mo·ni·ae n. Pneumococcus. Streptococcus pneumoniae Microbiology A pathogenic streptococcus with 90 serotypes associated with pneumonia, bacteremia, meningitis Transmission Person to person Incidence , methicillin-resistant Staphylococcus aureus methicillin-resistant Staphylococcus aureus Methicillin-aminoglycoside resistant Staphylococcus aureus, MRSA An organism with multiple antibiotic resistances–eg, aminoglycosides, chloramphenicol, clindamycin, erythromycin, rifampin, tetracycline, , and vancomycin-resistant Enterococcus vancomycin-resistant enterococcus Infectious disease An enterococcus, primarily Enterococcus faecium, resistant to most antibiotics, including aminoglycosides and vancomycin, once a 'last-resort' agent; VRE is primarily nosocomial, in long faecium resistance is mediated by the acquisition of genes or gene fragments by horizontal transfer; resistance in the treated host is a relatively rare event. For these organisms, indirect, population-level mechanisms of selection account for the increase in the prevalence of resistance. These mechanisms can operate even when treatment has a modest, or even negative, effect on an individual host's colonization with resistant organisms. ********** The growth of antimicrobial resistance has prompted calls to reduce unnecessary antibiotic use and to improve treatment protocols to maximize the lifespan of these drugs. These calls rest on the well-supported idea that the use of antimicrobial agents is a powerful selective force that promotes the emergence of resistant strains. To reduce antimicrobial resistance, multiple, and often conflicting recommendations, have been made. For example, strategies to minimize the burden of resistance in hospitals have included reduction of all antimicrobial classes, increased use of prophylactic antimicrobials to reduce colonization, rotation of different antibiotic classes in a temporal sequence, and simultaneous use of different antimicrobials for different patients (1-6). Underlying these often varying recommendations for improving antimicrobial use is frequently conflicting evidence about the relationship between antibiotic treatment and antibiotic resistance antibiotic resistance, n the ability of certain strains of microorganisms to develop resistance to antibiotics. antibiotic resistance . In some pathogens, showing that antibiotic treatment puts treated persons at a greater risk for acquiring resistant organisms has been difficult (7-8); nonetheless, the cumulative effect of using these antibiotics has clearly been to increase the prevalence of resistance in the population as a whole. For many pathogens of current concern, especially organisms for which asymptomatic colonization typically precedes infection (e.g., Streptococcus pneumoniae, Staphylococcus aureus Staphylococcus au·re·us n. A bacterium that causes furunculosis, pyemia, osteomyelitis, suppuration of wounds, and food poisoning. Staphylococcus aureus Staphylococcus pyogenes , Enterococcus enterococcus /en·tero·coc·cus/ (en?ter-o-kok´us) pl. enterococ´ci an organism belonging to the genus Enterococcus. Enterococcus /En·tero·coc·cus/ ( spp., and the gram-negative enteric bacteria Noun 1. enteric bacteria - rod-shaped Gram-negative bacteria; most occur normally or pathogenically in intestines of humans and other animals enterics, enterobacteria, entric ), the relationship between antimicrobial use and resistance differs in fundamental ways from the relationship found in Mycobacterium tuberculosis Mycobacterium tuberculosis n. Tubercic bacillus. Mycobacterium tuberculosis , for which many modern principles of chemotherapy were developed. Furthermore, we argue that the selective effects of antibiotic use on these organisms are poorly understood, and we make specific suggestions for studies that could improve understanding of the mechanisms by which antibiotics exert natural selection on these organisms. Such an understanding will be crucial for the design of rational policies of antibiotic use to maximize the lifespan of existing drugs and to minimize the impact of resistant infections. Resistance in People and Populations Ehrlich's advice that treatment of infections should "hit hard and hit early," formulated in the earliest days of antimicrobial chemotherapy, presciently pre·scient adj. 1. Of or relating to prescience. 2. Possessing prescience. [French, from Old French, from Latin praesci summarized the principles of treatment for infections such as tuberculosis (TB) (9). These principles are embodied in modern protocols of directly observed, short-course chemotherapy, where the goal is to treat with adequate concentrations of multiple drugs and maintain treatment until the bacterial population is extinct. Resistance to each of the major antituberculosis drugs Antituberculosis Drugs Definition Antituberculosis drugs are medicines used to treat tuberculosis, an infectious disease that can affect the lungs and other organs. is mediated by single point mutation point mutation n. A mutation that involves a single nucleotide and may consist of loss of a nucleotide, substitution of one nucleotide for another, or the insertion of an additional nucleotide. ; therefore tuberculosis treatment Active tuberculosis will kill about two of every three people affected if left untreated. Treated tuberculosis has a mortality rate of less than 5% (or less in developed countries where intensive supportive measures are available). is designed to prevent the ascent of subpopulations of mutant bacilli bacilli /ba·cil·li/ (bah-sil´i) plural of bacillus. bacilli see bacillus. that are resistant to any one of the drugs. Similar principles have been suggested for other infections in which resistance can arise by simple mutation, most notably HIV HIV (Human Immunodeficiency Virus), either of two closely related retroviruses that invade T-helper lymphocytes and are responsible for AIDS. There are two types of HIV: HIV-1 and HIV-2. HIV-1 is responsible for the vast majority of AIDS in the United States. (9), although there has been some controversy on this topic (11). In these infections, the relationship between treatment, resistance in the treated person, and resistance in the community at large is relatively clear. Inadequate therapy (owing to owing to prep. Because of; on account of: I couldn't attend, owing to illness. owing to prep → debido a, por causa de subtherapeutic sub·ther·a·peu·tic adj. Below the dosage levels used to treat diseases: subtherapeutic feeding of penicillin to livestock. sub drug concentrations, too few drugs, or poor adherence to therapy) results in the emergence of resistance, and possibly treatment failure, in the treated host. Following the emergence of resistance in the treated host, resistant infections may be transmitted to others. (Figure, A; Table). [FIGURE OMITTED] For many pathogens, both the genetics and the epidemiology of resistance differ from those of TB in important ways. For example, methicillin methicillin /meth·i·cil·lin/ (meth?i-sil´in) a semisynthetic penicillin highly resistant to inactivation by penicillinase; used as the sodium salt. meth·i·cil·lin n. resistance in S. aureus The aureus (pl. aurei) was a gold coin of ancient Rome valued at 25 silver denarii. The aureus was regularly issued from the 1st century BC to the beginning of the 4th century AD, when it was replaced by the solidus. and vancomycin vancomycin (văn'kōmī`sĭn), antibiotic resembling penicillin in the way it acts. It is derived from the bacterium Streptomyces orientalis, which was isolated from soil of India and Indonesia. resistance in Enterococcus are mediated by the acquisition of one or several new genes, rather than by point mutations in existing genes. In Streptococcus pneumoniae, penicillin resistance occurs when segments of wild-type penicillin-binding protein genes are replaced with alleles whose sequences differ from the wild-type at multiple positions. These new resistance mechanisms arose and spread in large populations under conditions of antibiotic selection pressure, but they are unlikely to occur de novo [Latin, Anew.] A second time; afresh. A trial or a hearing that is ordered by an appellate court that has reviewed the record of a hearing in a lower court and sent the matter back to the original court for a new trial, as if it had not been previously heard nor decided. in any single person because of the multiple changes involved. Organisms (or plasmids) bearing these types of resistance must be acquired, generally as a consequence of cross-transmission. Furthermore, most of these organisms are not obligate obligate /ob·li·gate/ (ob´li-gat) pertaining to or characterized by the ability to survive only in a particular environment or to assume only a particular role, as an obligate anaerobe. pathogens such as HIV or TB; as a result, much of their exposure to antibiotics occurs during treatment directed at infections caused by other, unrelated organisms. Because of these genetic and epidemiologic differences, the paradigm for tuberculosis treatment, minimizing resistance in the treated host and the community by preventing the emergence of resistant subpopulations during treatment, is often inapplicable in·ap·pli·ca·ble adj. Not applicable: rules inapplicable to day students. in·ap to these organisms (12). Antibiotic treatment promotes the spread of these organisms, as suggested by the rapid increases in resistance in many of the organisms after the new drug classes are introduced. However, the effects of treatment in promoting resistance occur by less direct mechanisms, which depend on competitive interactions between drug-resistant and drug-susceptible strains. Indirect Effects on Resistance For any infectious disease Infectious disease A pathological condition spread among biological species. Infectious diseases, although varied in their effects, are always associated with viruses, bacteria, fungi, protozoa, multicellular parasites and aberrant proteins known as prions. , the infection or colonization status of any one (index) patient affects the risk of infection or colonization of others. Measures (such as vaccination or antibiotic treatment) that change the incidence or duration of infection in one person will affect that person's contacts (13-14). Just as vaccination programs benefit those who are not vaccinated because of the phenomenon of herd immunity herd immunity n. 1. Resistance to the spread of infectious disease in a group because susceptible members are few, making transmission from an infected member unlikely. 2. , antibiotic usage by some persons may increase the risk of colonization or infection with resistant organisms in people who have not received antibiotics. Members of a population experience indirect effects of antimicrobial use, defined as the enhancement of risk for acquiring a resistant organism, because of the use of antimicrobials by other persons in the group or population. For example, simply by eradicating susceptible organisms, and thereby reducing the opportunities for transmission of susceptible strains, antibiotics received by treated hosts can increase the probability that other hosts will acquire resistant variants (Figure, B; Table). For many pathogens, acquisition of one strain reduces a person's chances of acquiring other strains, either via immune responses, via direct interference (15-17), or both. These inhibitory interactions create competition between resistant and susceptible strains. As a result, treatment of some patients, by eradicating susceptible strains and thereby reducing their ability to transmit to other hosts, is advantageous to resistant strains in the population. Mathematical models (18-22) and epidemiologic studies (23) suggest that this mechanism of shifting the competitive balance in favor of resistant strains can increase the prevalence of resistant organisms in the community, alone or in combination with other mechanisms. An important feature of this kind of indirect effect is that it need not involve an increase in a patient's own risk of carrying resistant organisms, only a reduction in the duration or probability of carrying susceptible ones. In these organisms, the increase in transmission of resistant pathogens is a consequence of successful treatment of the infected host, resulting in the eradication of drug-susceptible pathogens that colonize col·o·nize v. col·o·nized, col·o·niz·ing, col·o·niz·es v.tr. 1. To form or establish a colony or colonies in. 2. To migrate to and settle in; occupy as a colony. 3. or infect that host. As a consequence, the more effective a treatment is at eradicating drug-susceptible populations of these organisms, the more it will promote the spread of resistant ones. This spread contrasts with TB, in which treatment failure is often associated with the emergence of resistance in treated hosts, so unsuccessful treatment is seen as a factor promoting the spread of resistance (although, over a time scale of decades, this type of indirect mechanism described here may play a role even in tuberculosis [21]). Combinations of Direct and Indirect Effects on Resistance A third mechanism by which antimicrobial use increases the number of patients colonized Colonized This occurs when a microorganism is found on or in a person without causing a disease. Mentioned in: Isolation or infected with resistant organisms is by modifying the treated host's colonization resistance (Figure, C; Table). Eradication or reduction of drug-susceptible normal flora Normal flora The mixture of bacteria normally found at specific body sites. Mentioned in: Sputum Culture, Wound Culture by antibiotic treatment may increase vulnerability to acquisition of new strains. This effect will increase the patient's probability of being colonized with a resistant organism if, during or shortly after treatment, he or she is exposed to others with resistant organisms. This mechanism is direct in the sense that it increases the treated patient's risk of colonization with resistant organisms but is also associated with indirect effects because of the requirement for transmission. An index host given antibiotics is placed at greater risk for colonization with resistant organisms (direct effect), but this risk is amplified by his or her exposure to other patients harboring resistant organisms, which is in turn enhanced by their use of antibiotics (indirect effect). A fourth mechanism by which antimicrobial use increases antimicrobial resistance is by increasing the density of resistant organisms within a patient who already harbors such organisms at a lower density (Figure, D; Table). Enhanced shedding of these organisms, resulting in an increased risk to other patients (an indirect effect), has been documented (i.e., in the case of anti-anaerobic agents that increase shedding of vancomycin-resistant Enterococci enterococci bacteria in the genus Enterococcus. (VRE VRE vancomycin-resistant enterococcus. VRE Vancomycin-resistent enterococcus, see there ) (24). An increased risk of resistant infection to the treated patient (a direct effect) may occur if a higher density of resistant organisms places the patient at higher risk of infection with his or her own flora. Unlike the other three ways by which antimicrobial use promotes resistance, this mechanism is mediated through antimicrobial treatment of patients already colonized with the resistant organism. There are a number of other cases in which direct and indirect effects of antibiotic treatment are combined. Due to the diversity of genetic mechanisms of resistance, the risk of emergence of resistance during treatment represents a continuum, with TB at one end and VRE (or MRSA MRSA Methicillin-resistant Staphylococcus aureus. See MARSA. ) at the other. Fluoroquinolone fluoroquinolone /flu·o·ro·quin·o·lone/ (-kwin´o-lon) any of a subgroup of fluorine-substituted quinolones, having a broader spectrum of activity than nalidixic acid. fluor·o·quin·o·lone n. resistance in S. pneumoniae mediated by the accumulation of mutations in the DNA gyrase DNA gyrase (ji´ras) a type II DNA topoisomerase. and topo-isomerase IV genes (25), or resistance to third-generation cephalosporins Cephalosporins Definition Cephalosporins are medicines that kill bacteria or prevent their growth. Purpose Cephalosporins are used to treat infections in different parts of the body—the ears, nose, throat, lungs, sinuses, and in Enterobacteriaceae mediated by mutations in TEM TEM 1. transmission electron microscope. 2. triethylenemelamine. 3. transmissible encephalopathy of mink. and SHV SHV Shareholder Value SHV Standard High Volume SHV Sheave SHV Steenkolen Handels Vereeniging SHV Shreveport, LA, USA - Regional Airport (Airport Code) SHV Sport Horse Versatility SHV Supersonic/Hypersonic Vehicle SHV Super Hybrid Vehicle beta-lactamases located on plasmids (26), lie between these two extremes. In these cases, multiple mutations are required to turn a fully susceptible strain into a clinically resistant one. For a patient colonized or infected with a fully susceptible strain, emergence of resistance during treatment may be highly unlikely because of the requirement for selecting multiple mutations. However, in such cases, there may be selection in consecutive hosts for small increases in levels of resistance to a particular compound, resulting eventually in the emergence of clinical resistance (27). Patients may be colonized with a mixed flora of resistant and susceptible organisms, and eradication of the drug-susceptible flora may permit outgrowth of the resistant subpopulation sub·pop·u·la·tion n. A part or subdivision of a population, especially one originating from some other population: microbial subpopulations. Noun 1. (28). This mechanism has some formal similarity to what occurs in TB, except that for a colonizing bacterium such as the pneumococcus pneumococcus Spheroidal bacterium (Streptococcus pneumoniae) that causes human diseases including pneumonia, sinusitis, ear infection, and meningitis. Usually occurring in the upper respiratory tract, this gram-positive (see or the enteric enteric /en·ter·ic/ (en-ter´ik) within or pertaining to the small intestine. en·ter·ic adj. 1. Of, relating to, or within the intestine. 2. colonizers, outgrowth of resistant organisms in the site of colonization need not be associated with treatment failure. In these cases, the treated patient is at increased risk of carrying resistant organisms (direct effect), but an indirect effect on the population occurs because the treated patient no longer carries susceptible organisms and is, therefore, unable to transmit them. Treatment with one antimicrobial drug can select for resistance to a number of other, unrelated agents, by several means. If individual organisms are resistant to multiple drugs, then use of any one of these may promote resistance to others (29). Additionally, by altering the balance of different components of the indigenous microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. flora, treatment with one agent may increase the load of a pathogen resistant to another agent, simply by killing off competing flora of different species; this has been observed, for example, with anti-anaerobic treatments that increase the load of VRE (24). These complexities increase the number of relationships that need to be studied in assessing the effects of antimicrobial use on resistance and also the number of potential confounders in any study. Implications for Evaluating Treatment Strategies Variation in mechanisms of resistance has implications for the choice of antimicrobial therapy and the evaluation of strategies to minimize resistance. Adopting the individual and population-level perspective informs therapeutic decision-making, clinical study design, and public policy. In TB, preventing the emergence of resistance in a treated host is a sound policy for averting the emergence of resistance at the population level as well (although once resistant strains have emerged, special measures Special measures is a status applied by Ofsted, the schools inspection agency, to schools in England when it considers that they fail to supply an acceptable level of education and appear to lack the leadership capacity necessary to secure improvements. are required to contain them [30]). With respect to antimicrobial resistance, what is good for the patient is good for the population. In contrast, for other types of resistance, antimicrobial treatment may exert individual-level effects that are substantially different in magnitude or even opposite in direction to that of population-level effects. Treatment with a beta-lactam may produce only a small, short-lived increase in the treated patient's odds of carrying or being infected by a resistant pneumococcus (7). In some cases, treatment may actually eradicate carriage of a resistant organism, thereby reducing the individual's risk of resistant carriage. Small or unobservable effects on individual risk have been observed in other cases as well, such as vancomycin use for VRE (8, 31) and the use of various antibiotics for infections with resitant gram-negative rods (32). In these cases, preventing resistance in the treated patient may not be the central goal of a prudent antibiotic use policy; instead, treatment should seek to minimize the advantage it provides to resistant organisms in the community or the hospital as a whole, subject to the constraint of providing effective treatment for the patient. The considerations of the distinctive biologic and epidemiologic mechanisms of antibiotic resistance in different pathogens lead to several broad suggestions for future studies. First, the optimal study design to estimate individual-level effects of antibiotics on colonizing organisms such as VRE and beta-lactam resistant S. pneumoniae is to measure acquisition and loss rates in an observational cohort or experimental study where subjects are serially cultured before, during, and after antibiotic therapy (23, 33). Time-to-event statistical models (e.g., Cox proportional hazards regression) are appropriate analytic methods for these kinds of studies (23, 31, 34). This design allows investigators to distinguish between the effects of antimicrobials on the risk for acquisition (colonization) and their effects on the risk for clinical infection once an patient has been colonized with a resistant organism. As a consequence of the mechanisms we have described, the magnitude of an antibiotic's effect on a patient's risk of resistant colonization or infection may be dependent on his or her exposure to potential transmission of resistant organisms (13). Stated differently, the frequency of contact with others carrying the resistant organisms is likely an important effect-modifier of antibiotic effects for pathogens that do not follow the simple model of emergence of resistance exhibited by organisms such as M. tuberculosis M. tuberculosis, n the bacterium responsible for tuberculosis, generally a respiratory infection in man; nonrespiratory tuberculosis is considered an indicator disease for AIDS. See also tuberculosis. . Individual-level antibiotic effects mediated by alterations in colonization resistance or killing of susceptible bacteria may be greater in settings of high exposure to resistant organisms, for example, during outbreaks (7). Controlling for transmission risk or measuring effects conditional on a specified level of transmission risk is advised, when possible. Standard analytic approaches make the assumption that outcomes in different subject are independent, but this assumption is violated in the case of infectious diseases infectious diseases: see communicable diseases. . Use of one of these strategies to model exposure to transmission will help to account for this nonindependence of outcomes in different persons in the same study (13, 35-37). One practical result of quantifying direct, individual-level antibiotic effects is to PrOvide information on the short-term risk of infection with a resistant organism to a person about to initiate antibiotic treatment. This hazard needs to be taken into account when weighing the risks and benefits of use of antimicrobial agents in individual patients. However, analogous to the evaluation of vaccine programs, combined direct and indirect antibiotic effects carry increased importance from the public health and policy management perspective (38, 39). The measurement of population-level effects of antimicrobials also has educational value in demonstrating to clinicians and patients the extent to which individual antibiotic use choices have negative consequences for the population as a whole. Such a conflict between individual benefit and the population's harm is an example of what economists term an "externality Externality A consequence of an economic activity that is experienced by unrelated third parties. An externality can be either positive or negative. Notes: Pollution emitted by a factory that spoils the surrounding environment and affects the health of nearby residents is " or what environmentalists have called the "Tragedy of the Commons The Tragedy of the Commons is a type of social trap, often economic, that involves a conflict over resources between individual interests and the common good. The "Tragedy of the Commons" is a structural relationship between free access to, and unrestricted demand for a " (40). To estimate overall antibiotic effects from data requires group-level studies. Observational group-level studies may lack sufficient data to avoid confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor and other causes of ecologic bias (41). For this reason, studies that estimate the effects of individual- and group-level antimicrobial use are generally preferable to ones that contain group-level data alone. Depending on the context, the appropriate group(s) may include the family, the community, the hospital, or the hospital unit or department (42-44). Further research is necessary to evaluate hierarchical regression methods and compare results obtained from different levels of analysis (44). For the most accurate measurement of overall antibiotic effect on resistance in communities, a cluster-randomized intervention trial is appropriate (45). In cluster-randomized trials, the unit of randomization randomization (ranˈ·d  ·m is a group such as a community or a hospital, and multiple
units (sometimes as few as six, but often more) are assigned to each of
two (or more) treatment arms. We are not aware of published studies
using this design to evaluate antibiotic resistance, although we know of
two in progress (R. Platt, pers. comm.) (12). However, this design has
been used in other areas of infectious disease epidemiology for which
group level effects are important (such as vaccination programs), and it
is considered the standard design for investigations of the effects of
insecticide-impregnated bednets in preventing malaria (45-47). In the
context of antimicrobial resistance, cluster-randomized trials have two
key advantages. First, unlike studies that gather individual-level data
alone, they provide the opportunity to observe the indirect effects of
treatment on resistance. Second, they provide a clean way to avoid the
statistical problems of nonindependence between patients in a study that
may reduce the power or increase the false-positive rate of
observational studies observational studies,n.pl an investigational method involving description of the associations be-tween interventions and outcomes. Outcomes research and practice audits are examples of this investigational method. . In cluster-randomized studies of antimicrobial resistance, both the incidence rate of infection with resistant organisms in the population and the ratio of resistant to susceptible (or proportion of total organisms that are resistant) would be appropriate study endpoints. Role of Mathematical Models Transmission-dynamic modeling can also play an important role in bridging the gap between individual- and group-level effects (20, 21, 48-50). These models take information about individual-level effects as parameters and make predictions about the response of the population to changes in such parameters as transmission risk or antibiotic usage. Although models cannot substitute for empirical intervention studies intervention studies, n.pl the epidemiologic investigations designed to test a hypothesized cause and effect relation by modifying the supposed causal factor(s) in the study population. , they can be particularly valuable in at least four ways: 1) generating hypotheses about the relationship between antibiotic use and resistance that can be used in designing and prioritizing empirical studies Empirical studies in social sciences are when the research ends are based on evidence and not just theory. This is done to comply with the scientific method that asserts the objective discovery of knowledge based on verifiable facts of evidence. ; 2) defining the conditions under which a particular intervention is likely to work, thereby suggesting how empirical results can (and cannot) be extrapolated to other settings; 3) providing explanations for phenomena that have been observed but whose causes were uncertain; and 4) identifying biological mechanisms that, while important, remain poorly understood. An example of models for generating hypotheses comes from the question of antimicrobial rotation or "cycling." Cycling of antimicrobial classes in hospitals has been suggested and is currently being evaluated for its ability to curtail resistance in major nosocomial nosocomial /noso·co·mi·al/ (nos?o-ko´me-il) pertaining to or originating in a hospital. nos·o·co·mi·al adj. 1. Of or relating to a hospital. 2. pathogens (5, 51-54). One mathematical model of this process has suggested that using a mixture of different drug classes simultaneously (e.g., if two drug classes are available for empiric therapy Empiric therapy is a medical term referring to the initiation of treatment prior to determination of a firm diagnosis. It is most often used when antibiotics are given to a person before the specific microorganism causing an infection is known. of certain infections, treat half of the patients with one drug class and half with the other) will reduce resistance more effectively than cycling under a broad range of conditions (19). This suggests that such mixed regimens would be good candidates for comparison with cycling in controlled trials. As a second example, levels of resistance in hospital-acquired pathogens may change rapidly within a matter of weeks or months after changes in antimicrobial use. By contrast, studies of reductions in antimicrobial use in communities have shown slow and equivocal effects on resistance in community-acquired pathogens (55). Mathematical models suggest that, in communities, the key factor driving the change in resistance levels may be the "fitness cost" of resistance, i.e., resistance will decline after a reduction in antimicrobial use if resistant organisms in untreated patients are at a disadvantage for transmission or persistence (20, 50, 56-57). This cost may be small in many bacteria, accounting for the slow response (55, 58). In contrast, a model indicates that, in hospitals, changes in resistance may be driven primarily by the admission of new patients who often bring with them drug-susceptible flora, and this may rapidly "dilute" levels of resistance in the absence of continuing selection by antibiotics (59). If correct, this explanation suggests that the success of antimicrobial control measures should be evaluated differently for hospitals and for communities. The use of mathematical models, and more generally the attempt to predict the relative merits of different interventions, will depend on an improved understanding of the mechanisms of antibiotic selection in particular organisms. For example, two recently published models for the nosocomial spread of resistant pathogens made contrasting assumptions about whether antimicrobial treatment increased an patient's susceptibility to colonization only during treatment (60) or for a period following treatment (59), and about the importance of colonization with drug-susceptible strains in protecting against acquisition of resistant ones. As a result of these differences in assumptions, predictions differed in important ways: one model suggested that reduction of antibiotic use would be a comparatively poor intervention when endemic transmission is high and that resistant organisms could persist endemically even in the absence of input from admitted patients or antibiotic selection (60). The other model predicted rapid declines in the level of resistance when use is reduced, and a more complicated relationship between the effectiveness of interventions and the level of transmission within the hospital (59). Testable predictions will permit the evaluation of different models for particular settings and provide a basis for refining the assumptions of these models. Conclusion The relationship between antibiotic usage and antibiotic resistance for many types of pathogens is largely mediated by indirect effects or population-level selection. When resistant and susceptible organisms compete to colonize or infect hosts, and use of an antibiotic has a greater impact on the transmission of susceptible bacteria than resistant ones, then increasing use of the antibiotic will result in an increase in frequency of organisms resistant to that drug in the population, even if the risk for treated patients is modest. Antimicrobial use and patient-to-patient transmission are not independent pathways for promoting of antimicrobial resistance, rather they are inextricably in·ex·tri·ca·ble adj. 1. a. So intricate or entangled as to make escape impossible: an inextricable maze; an inextricable web of deceit. b. linked. Study designs to assess the effect of antimicrobial use on resistance should reflect these diverse pathways of direct and indirect effects. Estimates of direct effects of antimicrobial use on treated patients will be most informative if clinical cultures are combined with measurements of colonization. Use of time-to-event (e.g., Cox proportional hazards) models provides a natural way of controlling for the patient's length of stay when assessing the effect of treatment on acquisition of resistant organisms. Analyses that control for a person's exposure to other patients carrying resistant organisms will help to capture the effect modification effect modification Epidemiology An interaction among multiple possible cause-and-effect relationships, where the estimate of the effect of one factor on a disease process depends on other factors in the study because of varying transmission pressures during a study. Inclusion of data on antimicrobial use by the group to which others are exposed (siblings, fellow patients on a hospital unit, total use in a community) and to individual-level data will provide one method of estimating both direct and indirect effects of antibiotic use. Nonindependence of individual outcomes makes the interpretation of intervention studies problematic unless measures are taken to account for this nonindependence; cluster-randomized studies, used in other areas of infectious disease epidemiology, are an excellent solution to this problem. We have commented elsewhere on other aspects of study design for antimicrobial resistance, notably the importance of control group selection (7, 61-62). Understanding in detail, for each pathogen, the mechanisms by which antimicrobial use selects for antimicrobial resistance in treated patients and in the population is of more than academic importance. For practitioners, these mechanisms matter for making well-informed decisions about the design of treatment protocols, the choice of antibiotics and doses for particular indications. For policymakers, these issues have direct bearing on the design of campaigns to encourage more rational antibiotic use and on the priorities in regulating the use of antimicrobial agents for human and animal use (63-64).
Table. Mechanisms by which antimicrobial treatment has direct and
indirect effects on resistance
Relationship Relationship
between between no./
selection for dose of
resistance and antibiotics
Mechanism (effect of treatment) treatment success and selection
Emergence of resistance [down arrow] (d) [down arrow]
during treatment (D (a), I (b))
Reduced transmission of [up arrow] (e) [up arrow]
susceptible strains (1)
Increased susceptibility to ? (c) ?
colonization (D, I)
Increased density of colonization ? [up arrow] - ?
in individuals already colonized
with resistant organisms, by
inhibiting competitors (D,I)
Mechanism (effect of treatment) Examples Figure
Emergence of resistance TB, HIV, Pseudomonas 1a
during treatment (D (a), I (b)) aeruginosa, Enterobacter
spp.
Reduced transmission of May occur for nearly lb
susceptible strains (1) every infection
Increased susceptibility to Commensals of skin, 1c
colonization (D, I) intestinal and respiratory
tracts
Increased density of colonization VRE (f) and anti- 1d
in individuals already colonized anaerobic treatments
with resistant organisms, by
inhibiting competitors (D,I)
(a) D=direct.
(b) I=indirect.
(c) ?=relationship uncertain.
(d) [down arrow] inverse relationship.
(e) [up arrow] positive relationship.
(f) VRE=vancomycin-resistant Enterococci.
Acknowledgments We thank Anthony Harris Anthony James Harris (b. 26 June, 1982) in Dunedin. He is a New Zealand cricketer who has played for the Otago Volts in the State Championship and he also plays for Central Otago in the Hawke Cup. , Stephanie Schrag, and Yehuda Carmeli for helpful discussions and Fernando Baquero, Woody Spruance, Merle merle a pattern of coat color pigmentation with dark, irregular blotches on a lighter background. Seen in some Collies and Welsh corgis. In shorthaired dogs, e.g. Great Danes and Dachshunds, the similar pattern is called dapple. Sande, Dale Gerding, and Robert Moellering for useful criticism of an earlier draft. References (1.) Price DJ, Sleigh sleigh: see sled. JD. Control of infection due to Klebsiella klebsiella Any of the rod-shaped bacteria that make up the genus Klebsiella. They are gram-negative (see gram stain), thrive better without oxygen than with it, and do not move. 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(29.) Enne VI, Livermore DM, Stephens P, Hall LM. Persistence of sulphonamide sulphonamide or US sulfonamide Noun Pharmacol any of a class of organic compounds that prevent the growth of bacteria resistance in Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. in the UK despite national prescribing restriction. Lancet 2001;357(9265):1325-8. (30.) Becerra MC, Bayona J, Freeman J, Farmer PE, Kim JY. Redefining MDR-TB MDR-TB Multi-Drug Resistant Tuberculosis transmission "hot spots hot spots acute moist dermatitis. ." Int J Tuberc Lung Dis 2000;4:387-94. (31.) Bonten MJ, Slaughter S, Ambergen AW, Hayden MK, van Voorhis J, Nathan C, et al. The role of"colonization pressure" in the spread of vancomycin-resistant enterococci: an important infection control variable. Arch Intern Med 1998;158:1127-32. (32.) 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Clostridium difficile Clostridium difficile A common cause of bacterial colitis; it is the causative agent in 99% of pseudomembranous colitis, and 20-30% of antibiotic-associated diarrhea colonization and diarrhea at a tertiary care tertiary care Managed care The most specialized health care, administered to Pts with complex diseases who may require high-risk pharmacologic regimens, surgical procedures, or high-cost high-tech resources; TC is provided in 'tertiary care centers', often hospital. Clin Infect Dis 1994;18:181-7. (35.) Halloran ME. Concepts of infectious disease epidemiology. In: Rothman KJ, Greenland S, editors. Modern Epidemiology, 2nd Ed. Philadelphia: Lippincott-Raven; 1998. p. 529-554. (36.) Koopman JS, Longini IM, Jr. The ecological effects of individual exposures and nonlinear disease dynamics in populations [see comments]. Am J Public Health 1994;84:836-42. (37.) Koopman JS, Lynch JW. Individual causal models and population system models in epidemiology. Am J Public Health 1999;89:1170-4. (38.) Haber M. Estimation of the direct and indirect effects of vaccination. Stat Med 1999;18:2101-9. (39.) Halloran ME, Struchiner CJ, Longini IM, Jr. Study designs for evaluating different efficacy and effectiveness aspects of vaccines. Am J Epidemiol 1997;146:789-803. (40.) Hardin G. The tragedy of the commons. The population problem has no technical solution; it requires a fundamental extension in morality. Science 1968;162:1243-8. (41.) Greenland S, Robins J. Invited commentary: ecologic studies--biases, misconceptions, and counterexamples [see comments]. Am J Epidemiol 1994;139:747-60. (42.) Leibovici L, Berger R, Gruenewald T, Yahav J, Yehezkelli Y, Milo Milo, athlete of ancient Greece Milo (mī`lō) or Milon (mī`lŏn), fl. 500 B.C., athlete of ancient Greece, b. Crotona. G, et al. Departmental consumption of antibiotic drugs and subsequent resistance: a quantitative link. J Antimicrob Chemother 2001;48:535-40. (43.) Samore MH, Magill MK, Alder alder (ôl`dər), name for deciduous trees and shrubs of the genus Alnus of the family Betulaceae (birch family), widely distributed, especially in mountainous and moist areas of the north temperate zone and in the Andes. SC, Severina E, Morrison-De Boer L, Lyon JL, et al. High rates of multiple antibiotic resistance in Streptococcus pneumoniae from healthy children living in isolated rural communities: association with cephalosporin cephalosporin (sĕf'əlōspôr`ĭn), any of a group of more than 20 antibiotics derived from species of fungi of the genus Cephalosporium and closely related chemically to penicillin. Cephalosporins, e.g. use and intrafamilial transmission. Pediatrics 2001;108:856-65. (44.) Harbarth S, Harris A, Carmeli Y, Samore MH. Parallel analysis of individual and aggregated data on antibiotic exposure and resistance in Gram-negative bacilli. Clin Infect Dis 2001;33:1462-8. (45.) Hayes RJ, Alexander ND, Bennett S, Cousens SN. Design and analysis issues in cluster-randomized trials of interventions against infectious diseases. Stat Methods Med Res 2000;9:95-116. (46.) Moulton LH, O'Brien KL, Kohberger R, Chang I, Reid R, Weatherholtz R, Hackell JG, et al. Design of a group-randomized Streptococcus pneumoniae vaccine trial. Control Clin Trials 2001;22:438-52. (47.) Hayes RJ, Bennett S. Simple sample size calculation for cluster-randomized trials. Int J Epidemiol 1999;28:319-26. (48.) Austin DJ, Bonten MJM MJM Multi-Jet Modeling (prototyping manufacturing) MJM Metropolitan Japanese Ministry MJM Married Jewish Male , Weinstein RA, Slaughter S, Bergmans DCJ DCJ District Chief Judge (Toastmasters) , Stobberingh EE, et al. Characteristic dynamics of endemic colonization in intensive care units. In: 39th ICAAC ICAAC Interscience Conference on Antimicrobial Agents and Chemotherapy ICAAC Iowa Community College Athletic Conference ; 1999; San Francisco; 1999. p. 706. (49.) Austin DJ, Kristinsson KG, Anderson RM. The relationship between the volume of antimicrobial consumption in human communities and the frequency of resistance [see comments]. Proc Natl Acad Sci U S A 1999;96:1152-6. (50.) Austin DJ, Anderson RM. Studies of antibiotic resistance within the patient, hospitals and the community using simple mathematical models. Philos Trans R Soc Lond B Biol Sci 1999;354:721-38. (51.) Kollef MH, Vlasnik J, Sharpless L, Pasque C, Murphy D, Fraser V. Scheduled change of antibiotic classes: a strategy to decrease the incidence of ventilator-associated pneumonia [see comments]. Am J Respir Crit Care Med 1997;156(4 Pt 1):1040-8. (52.) Raymond DP, Pelletier SJ, Crabtree TD, Gleason TG, Hamm LL, Pruett TL, et al. Impact of a rotating empiric antibiotic schedule on infectious mortality in an intensive care unit. Crit Care Med 2001;29:1101-8. (53.) John JF Jr. Antibiotic cycling: is it ready for prime time? [editorial]. Infect Control Hosp Epidemiol 2000;21:9-11. (54.) McGowan JE, Jr. Minimizing antimicrobial resistance in hospital bacteria: can switching or cycling drugs help? Infect Control 1986;7:573-576. (55.) Lipsitch M. The rise and fall of antimicrobial resistance. Trends Microbiol 2001;9:438-44. (56.) Levin S, Pimentel D. Selection of intermediate rates of increase in parasite-host systems. American Naturalist 1981;117:308-15. (57.) Levin BR, Lipsitch M, Perrot V, Schrag S, Antia R, Simonsen L, et al. The population genetics Population genetics The study of both experimental and theoretical consequences of mendelian heredity on the population level, in contradistinction to classical genetics which deals with the offspring of specified parents on the familial level. of antibiotic resistance. Clin Infect Dis 1997;24(Suppl 1):S9-16. (58.) Andersson DI, Levin BR. The biological cost of antibiotic resistance. Curr Opin Microbiol 1999;2:489-493. (59.) Lipsitch M, Bergstrom CT, Levin BR. The epidemiology of antibiotic resistance in hospitals: paradoxes and prescriptions. Proc Natl Acad Sci U S A 2000;97:1938-43. (60.) Austin DJ, Bonten MJ, Weinstein RA, Slaughter S, Anderson RM. Vancomycin-resistant enterococci in intensive-care hospital settings: transmission dynamics, persistence, and the impact of infection control programs. Proc Natl Acad Sci U S A 1999;96:6908-13. (61.) Harris AD, Karchmer TB, Carmeli Y, Samore MH. Methodological principles of case-control studies that analyzed risk factors for antibiotic resistance: a systematic review. Clin Infect Dis 2001;32:1055-61. (62.) Harris AD, Samore MH, Carmeli Y. Control group selection is an important but neglected issue in studies of antibiotic resistance. Ann Intern Med 2000;133:159. (63.) Sande MA, Armstrong D, Corey L, Drew WL, Gilbert D, Moellering RC Jr., et al. Perspectives on switching oral acyclovir acyclovir /acy·clo·vir/ (a-si´klo-ver) a synthetic purine nucleoside with selective activity against herpes simplex virus; used as the base or the sodium salt in the treatment of genital and mucocutaneous herpesvirus infections. from prescription to over-the-counter status: report of a consensus panel. Clin Infect Dis 1998;26:659-63. (64.) Phillips I. Assessing the evidence that antibiotic growth promoters influence human infections. J Hosp Infect 1999;43:173-8. Marc Lipsitch is Assistant Professor of Epidemiology at Harvard School of Public Health The Harvard School of Public Health is (colloquially, HSPH) is one of the professional graduate schools of Harvard University. Located in Longwood Area of the Boston, Massachusetts neighborhood of Mission Hill, next to Harvard Medical School and Cambridge, Massachusetts, . He uses experimental (animal model), epidemiologic, and mathematical modeling approaches to study the population biology of antimicrobial resistance and to assess the effects of vaccination on the population structure of Streptococcus pneumoniae. Matthew Samore is Associate Professor of Internal Medicine at the University of Utah The University of Utah (also The U or the U of U or the UU), located in Salt Lake City, is the flagship public research university in the state of Utah, and one of 10 institutions that make up the Utah System of Higher Education. and Chief of the Division of Clinical Epidemiology. He attended the University of Wisconsin School of Medicine, completed his residency in Internal Medicine at Washington University in St. Louis “Washington University” redirects here. For other uses, see Washington (disambiguation). Washington University in St. Louis is a private, coeducational, research university located in St. Louis, Missouri. , and a fellowship in Infectious Diseases at Brigham and Women's Hospital Brigham and Women's Hospital (BWH) is a hospital in the Longwood Area of the Boston, Massachusetts neighborhood of Mission Hill. With Massachusetts General Hospital, it is one of the two founding members of Partners HealthCare. and Beth Israel Hospital See:
Address for correspondence: Marc Lipsitch, Department of Epidemiology, Harvard School of Public Health, 677 Huntington Avenue, Boston, MA 02115; fax: 617-566-7805; e-mail: mlipsitc@hsph.harvard.edu Marc Lipsitch * and Matthew H. Samore ([dagger]) * Harvard School of Public Health, Boston, Massachusetts, USA; and ([dagger]) University of Utah School of Medicine, Salt Lake City, Utah For ships of the United States Navy of the same name, see . Salt Lake City is the capital and the most populous city of the U.S. state of Utah. The name of the city is often shortened to Salt Lake, or its initials, S.L.C. , USA |
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