Department of Infectious Diseases, University of Torino, Amedeo di Savoia Hospital, Corso Svizzera 164, 10149 Turin, Italy
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Abstract |
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Keywords: M. tuberculosis , multidrug-resistant tuberculosis , therapy , second-line agents
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Introduction |
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Inappropriate treatment of drug-susceptible tuberculosis and its consequences on the susceptibility of M. tuberculosis to existing medications |
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How multidrug resistance is defined in tuberculosis |
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How resistance to antituberculous drugs is generated |
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The selection of drug-resistant M. tuberculosis depends on the frequency of the specific drug-resistant mutants in the initially drug-susceptible bacterial population. As a consequence, the chance of selecting such mutants is the highest in the case of monotherapy.2 Whilst mutants resistant to a single drug may be fairly easily selected by monotherapy, the probability of selecting mutants that are resistant to multiple drugs decreases exponentially by increasing the number of drugs to which M. tuberculosis is simultaneously exposed.2 The rationale for combination drug therapy was proven by a series of clinical demonstrations that provided unambiguous evidence of how the administration of multiple drugs bears a significantly lower chance of both disease recrudescence and selection of drug-resistant strains compared with monotherapy.2,4 Such clinical research eventually gave the current therapeutic strategy, which consists of three or four drugs in the initial phase of therapy, followed by a consolidation two-drug phase once the initial bacterial biomass has been reduced to such an extent that the chance of selecting residual drug-resistant mutants is exceedingly low.2
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Major differences between the treatment of drug-susceptible and drug-resistant tuberculosis |
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In terms of treatment duration, the greatest difference between drug-susceptible and MDR-TB is the lack of a real substitute for rifampicin, the crucial drug in short-course TB chemotherapy.3 The introduction of rifampicin allowed the duration of the length of antituberculous treatment to be reduced from 1824 months down to the currently accepted standard of 69 months.4 A major property that has been attributed to rifampicin is its ability to affect dormant bacilli.14 Whilst at the outset of anti-TB treatment, the vast majority of organisms are actively replicating and are therefore susceptible to anti-mycobacterial agents, in the subsequent phases of therapy, the residual M. tuberculosis population switches to a virtually inactive metabolic status which make these organisms poorly susceptible to drugs.2,4 It is thought that these inactive bacilli undergo periodic metabolic reactivation and that during these short periods of activity rifampicin is able to exert its action on the bacterial RNA polymerase, whilst these brief periods of time are insufficient for the other otherwise equally effective bactericidal agents to produce any appreciable effect.15
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Treating MDR-TB: essential clinical pharmacology of second-line antituberculous drugs |
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In clinical practice, an important feature of aminoglycosides and capreomycin is the need for parenteral administration.16,17 Aminoglycosides exert their effects by binding to the 30S subunit of bacterial ribosomes, thus leading to reduced mRNA reading and impaired protein synthesis.18 These drugs must penetrate into mycobacteria in order to reach their molecular targets. At low pH values, as in cavities or abscesses,19 drug penetration through bacterial porins is limited and this could be one of the reasons accounting for the clinical ineffectiveness of aminoglycosides as single anti-TB agents.19 Moreover, these molecules do not penetrate mammalian cells and therefore lack efficacy against intracellular bacteria.18,19 Aminoglycosides are bactericidal only against rapidly dividing mycobacteria, and have little or no activity against bacilli which are not replicating,18 such as those persisting for long periods in the stationary phase of growth. This is the pharmacodynamic rationale of using aminoglycosides only in the induction phase, when a large number of rapidly multiplying bacilli at the extracellular level are present, whilst in the maintenance phase agents active against intraphagocytic and slowly dividing mycobacteria are needed.2
Another crucial issue related to long-term administration of aminoglycosides is toxicity. Ototoxicity and nephrotoxicity are well recognized as dose-related adverse effects of aminoglycosides.20,21 Amikacin is reputed to be less vestibulotoxic and nephrotoxic than streptomycin and kanamycin and this could be advantageous in clinical practice, especially for long treatment periods.22 The toxicity profile of capreomycin is similar to that of aminoglycosides, including nephrotoxicity.23 A distinct clinical entity associated with capreomycin is a form of renal tubulopathy characterized by ion losses with resultant alkalosis.23
Resistance to streptomycin is more common in those areas where the drug has been more widely used.24 Ribosomal modifications due to mutations in the region of the S12 interaction with 16S rRNA, and particularly changes of the codon 43, are probably the main mechanisms of resistance,25 although other mechanisms are not excluded. The binding site of each of the aminoglycosides may be different, therefore the ribosomal mutations that mediate resistance to aminoglycosides are likely to be drug-specific.26 Amikacin is generally active against streptomycin-resistant strains of M. tuberculosis,27 whilst cross-resistance with kanamycin is the rule.26 On the other hand, strains resistant to amikacin are generally also resistant to streptomycin. Capreomycin, although very expensive for countries with limited resources, is also potentially active against streptomycin-resistant strains.26 Capreomycin-resistant strains are not usually resistant to amikacin, while the inverse seems to be the case for low-level, but not for high-level, amikacin resistance.26
p-Aminosalicylic acid (PAS)
Discovered in the 1940s, the antimycobacterial agent PAS was considered to be a first-line agent,28 in combination with isoniazid and streptomycin, until it was replaced by ethambutol in the early 1960s.29 PAS exerts a bacteriostatic effect on M. tuberculosis by competitively blocking the conversion of para-aminobenzoic acid into folic acid.30 PAS is usually given orally. The granular formulation now available is more easily administered and better tolerated than the original tablet formulation (2024 tablets per day).31 However, side effects related to PAS are frequent and include gastrointestinal symptoms, hypersensitivity reactions (up to 10%), hypothyroidism, thrombocytopaenia and intestinal malabsorption.31
Thioamides
Following the discovery of isoniazid, numerous pyridine derivatives were tested, with ethionamide and prothionamide being shown to have antimycobacterial activity.32 The mechanism of action is, like isoniazid, at the level of synthesis of mycolic acids.33 Both the drugs are bactericidal in vitro but resistance can rapidly emerge.32 The usual dosage is 5001000 mg per day in two doses. The most important adverse drug events are gastrointestinal disturbance and hepatotoxicity (hepatitis in 4.3% of patients), with ethionamide slightly less toxic than prothionamide.34,35 Other side effects include neuritis, convulsion, dizziness and gynaecomastia. Interestingly, isoniazid-resistant bacilli are usually susceptible to these thioamides, although they share the same parent compound, isonicotinic acid.33 Cross-resistance is complete between ethionamide and prothionamide.32
Cycloserine
Cycloserine exerts an antimycobacterial bacteriostatic effect by competitively blocking two metabolic steps of the biosynthesis of the bacterial cell wall.36,37 Clinical studies in the 1950s showed decreased efficacy compared with PAS, and severe dose-related neuropsychiatric toxicity.38 The latter is frequent (up to 50% of patients at the dose of 1 g/day) and includes convulsive seizures, psychotic episodes, slurred speech, drowsiness and coma.39 Smaller and divided doses reduce the frequency of adverse events.40 The oral dose used currently is 250 mg twice or three times a day, and therapeutic drug monitoring is advocated so as not to exceed plasma levels of 30 ng/mL.40
Rifamycins other than rifampicin
Rifabutin has considerable cross-resistance with rifampicin, with less than 15% of M. tuberculosis strains resistant to rifampicin retaining susceptibility to rifabutin.41 In this minor proportion of cases, some of the mutations selected by rifampicin do not modify the RNA polymerase sufficiently as to render this protein resistant to rifabutin.42 However, the proportion of discordant resistance is too low to make rifabutin a generally useful drug in rifampicin-resistant disease, and no clinical studies have addressed this issue.
The pattern and the mechanism of resistance of rifapentine is identical to that of rifampicin.43
Fluoroquinolones
Fluoroquinolones inhibit topoisomerase II (DNA gyrase) of M. tuberculosis.44 The other molecular target of fluoroquinolones, topoisomerase IV, is absent in M. tuberculosis.44 A notable property of fluoroquinolones relates to their ability to penetrate into macrophages and to exert intracellular mycobactericidal activity.45 Although the activity of fluoroquinolones against M. tuberculosis was already evident from the early pre-clinical in vitro screening,46 their use in the treatment of TB has never been formally pursued by the manufacturers for overt commercial reasons. Most clinical experience has been accumulated with first-generation fluoroquinolones, ofloxacin and ciprofloxacin,47 which are currently approved as second-line agents for MDR-TB by the WHO, American Thoracic Society, and Centers for Disease Control.10,48 However, the number of clinical studies examining the role of fluoroquinolones for MDR-TB is limited. Further to the clinical data available on ciprofloxacin and ofloxacin,4953 there are few reports regarding the use of sparfloxacin and levofloxacin.54,55 In most cases, ofloxacin was given at a dosage of 400 mg once a day and ciprofloxacin 500750 mg twice daily. However, more recently higher dosages have been used such as 800 mg ofloxacin and 1000 mg ciprofloxacin, both once daily.53,55 In a comparative trial,56 levofloxacin (which is the S enantiomer of ofloxacin) was found to be more efficacious than ofloxacin when incorporated into regimens used for treatment of MDR-TB. Adverse effects related to the administration of fluoroquinolones include gastrointestinal disturbances, neurological effects, arthropathy and photosensitivity.44,57
Promising data have been reported for the newer compounds, gatifloxacin58,59 and moxifloxacin.6062 The latter agents have significantly lower MICs for M. tuberculosis than older fluoroquinolones and better pharmacodynamic correlates (Table 2). Sparfloxacin was also shown to be six to eight times more active than ofloxacin (although less active than moxifloxacin and gatifloxacin), but serious photosensitivity limited its clinical use.63 The pharmacodynamic activity of fluoroquinolones is concentration-dependent. Parameters such as the peak serum concentration (Cmax) and the area under the concentrationtime curve (AUC) to the MIC therefore have to be considered as the best pharmacodynamic correlates of antimycobacterial efficacy.64 According to these parameters (Table 2), moxifloxacin at the recommended daily dose of 400 mg seems to be the most active fluoroquinolone against M. tuberculosis.65,66
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The selection of fluoroquinolone-resistant M. tuberculosis has been observed in vivo.69,70 Mutations of gyrA and gyrB genes are required for high-level resistance,44 although alternative resistance mechanisms, including energy-dependent active efflux, are probably involved.69 Complete cross-resistance within the class is the currently accepted rule.69 Potential advantages of high doses of newer compounds against low-level resistance to older fluoroquinolones has to be confirmed in further clinical evaluations.69 However, decreased susceptibility to fluoroquinolones can develop after short courses of empirical therapy (e.g. 1015 days), and the risk of selecting resistance before a diagnosis of tuberculosis is established has been described, particularly in HIV-positive subjects.69,70
Linezolid
Linezolid, an agent of the oxazolidinone class mainly used to treat infections caused by Gram-positive bacteria, has good antimycobacterial activity.71 It appears to inhibit protein synthesis by binding to the 50S ribosomal subunit.72 The literature currently available is very limited and no clinical data have yet been reported.
Clarithromycin
This macrolide has a spectrum of activity that includes mycobacteria,73 and it is frequently employed for the treatment of Mycobacterium avium complex infection. Concentrations which are effective against M. tuberculosis seem to be well above those achievable in serum and lung tissue of patients (MIC90>128 ng/mL)74,75 In animal models, however, clarithromycin showed an antituberculous activity, likely to result from its high intracellular accumulation.76 Interestingly, in vitro sub-inhibitory concentrations of cell wall inhibitors were shown to reverse intrinsic M. tuberculosis resistance to clarithromycin,77 probably by allowing a higher intracellular penetration of the drug. Moreover, clarithromycin was shown to restore, by an unknown mechanism, the in vitro antimycobacterial activity of first-line compounds (isoniazid, rifampicin and ethambutol) against MDR strains.78 However, no clinical data on the use of clarithromycin in the treatment of MDR-TB are available.
ß-Lactams
Co-amoxiclav and ampicillin/sulbactam have in vitro activity against M. tuberculosis.79 The ß-lactamase inhibitor is essential to overcome mycobacterial ß-lactamase hydrolysis and to allow penetration of the aminopenicillin through the cell wall.80,81 The EBA of co-amoxiclav was reported to be comparable to that of ofloxacin, supporting a potential role in the clinical setting.82 However, bactericidal activity against only exponential-phase and not stationary-phase bacilli suggested a potential clinical usefulness only in the early stages of treatment or as a supportive agent to prevent the selection of resistance against companion drugs.81 The anecdotal efficacy of co-amoxiclav-containing regimens for treatment of MDR-TB has been described, but definitive clinical evaluation has not yet been carried out.83,84
Clofazimine
Clofazimine, a riminophanazine used against Mycobacterium leprae and M. avium infections, is active against M. tuberculosis.85 Clofazimine concentrates in macrophages and was reported to be efficacious in a murine model of tuberculosis.85 No clinical data on its use for treating MDR-TB are currently available.
Phenothiazines
These compounds are currently used in the management of psychosis. Chlorpromazine has a titrable activity in the inhibition of the growth of intracellular M. tuberculosis in vitro.86 Thioridazine has also been shown to be active against MDR M. tuberculosis,87 although the cardiac safety profile is still under investigation. Phenothiazines have not yet been tested for their antimycobacterial activity in humans.
Nitroimidazopyrans
Newer compounds of this class (which includes metronidazole) were found to display a considerable activity against M. tuberculosis,88 through the inhibition of both protein and lipid synthesis. They also exert a bactericidal effect against bacilli in the stationary phase. A recently synthesized nitroimidazopyran was shown to act in vitro against MDR M. tuberculosis,89 and its clinical development seems warranted.
Other compounds
A series of chemically heterogeneous molecules are undergoing in vitro and in vivo testing, but very limited information on their development is currently available. Tuberactinomycin90 is a polypeptide active against amikacin-resistant strains that was found to be better tolerated than capreomycin in a preliminary clinical assessment in East Asia. Acetamides91 belong to a new class of compounds with specific and promising antimycobacterial activity. Pyrrole derivatives92 were shown to have bactericidal activity against MDR M. tuberculosis strains.
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Outcome of MDR-TB |
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Two major case series of MDR-TB outside the setting of HIV infection have been reported in some detail,103,104 respectively describing the outcome of 171 and 26 patients. In the study by Goble et al.,103 171 MDR-TB patients with a median age of 46 years who had received a median of six drugs before being retreated, and shed bacilli found to be resistant to a median of six drugs, had an overall response rate of 56%, while in the study by Telzak et al.,104 26 MDR-TB patients with a median age of 37 years and a prior exposure to a median of 3.5 drugs (only 35% had previously received some form of anti-TB treatment) had a 96% rate of treatment success. Taken together, these two studies give an informative picture of the major factors that determine the chances of curing MDR-TB. A lower prior exposure to anti-TB drugs, a higher number of anti-TB drugs to which the individual infection is still susceptible and a shorter time since the first TB diagnosis (indicating a less advanced disease) indicate a greater chance of successful treatment response. These findings have been confirmed by other studies, such as the French national survey by Flament-Saillour et al.105 Park et al.106 demonstrated that carefully selected regimens (preferably including four drugs to which the infection was proven to be fully susceptible) led to relatively high cure rates in a series of 107 Korean MDR-TB patients shedding bacilli initially resistant to a mean of four drugs. The importance of the number of antituberculous drugs to which MDR-TB isolates are still susceptible is also emphasized by the reports by Salomon et al.,107 Turett et al.,108 and Park et al.,109 who found that the prompt institution of appropriately selected regimens may even significantly improve the short-term outcome of MDR-TB in patients with HIV infection. In Mexico, Perez-Guzman et al.110 showed how in particularly favourable conditions, such as with limited baseline resistance and reliable laboratory information on drug susceptibility, MDR-TB in HIV-negative patients may even respond to regimens as short as 12 months.
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Principles and practice in the management of MDR-TB |
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A basic starting point is the access to a good diagnostic service. Although most microbiology departments are able to carry out basic microscopy and isolation of mycobacteria, the expertise required to carry out dependable drug-susceptibility testing is variable. When testing for second-line drugs is considered, the number of centres able to provide reliable results on drug susceptibility of M. tuberculosis is reduced to just one or two per country. In these centres, rapid methods to reduce time of diagnosis of MDR-TB and of susceptibility testing could play a crucial role. The radiometric BACTEC 460 technique has been proven to be reliable for second-line drug-susceptibility testing compared with the standard proportion method with solid media,112 whilst newer fully automated non-radiometric culture methods (e.g. MGIT 960, MB/BACT) have been evaluated only for first-line antituberculous agents.113,114 Among tools for rapid detection of resistance, a reverse hybridization-based probe assay (INNO-LiPA Rif TB) is available for detection of mutations in the rpoB gene for resistance to rifampicin,114,115 whilst many other amplification-based methods have been proposed for resistance to isoniazid, aminoglycosides and fluoroquinolones.116,117
When initiating or revising therapy, the general rule is never to add a single drug to a failing regimen: this will simply result in additional resistance. At least three, but preferably four or five, previously unused drugs whose in vitro activity is proven should be administered. In designing a regimen we should not aim to keep drugs in reserve: that is the way to lose the last battle. With adequate information, the choice of an anti-MDR-TB regimen becomes a stepwise process, with preference being given to the residual first-line agents shown to be still active, such as pyrazinamide, streptomycin and ethambutol. Resistance to one of the antituberculous aminoglycosides, most often streptomycin, generally still allows for the selection of another compound from this class. Depending on the local resources, a parenterally administered drug such as amikacin, capreomycin or kanamycin could potentially be included, in association with second-line oral agents (fluoroquinolones, ethionamide, PAS, cycloserine, clarithromycin, co-amoxiclav, linezolid) (Table 3). In making the selection of the latter, we propose a hierarchy (Table 4) based on their intrinsic activity against M. tuberculosis and clinical evidence of efficacy.
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Adherence is a major issue. Apart from the case of primary MDR-TB, a lack of treatment adherence in the past is typically the factor that has caused the patient to have MDR-TB. If proper action is not taken to ensure patient compliance, the chance of further treatment failure and increased resistance is high.118 Referral to adherence-promoting TB services is therefore important. Hospital-based treatment is advisable at least until sputum conversion occurs. After discharge, DOT should be given, particularly for cases of acquired resistance and prior evidence of non-adherence. In the bacteriological and clinical monitoring of response to therapy, it must be anticipated that improvement of MDR-TB is usually slower than with drug-susceptible TB. However, in most case series, patients who eventually became culture negative converted sputum sample after 23 months of therapy.98110
The role of surgery in the management of patients with extensive pulmonary disease has not been established in randomized studies. However, in some case series, patients with severe MDR-TB appeared to benefit from resection of damaged lung tissue,118120 especially when extensive and longstanding fibrosis is present and treatment failure occurred with a large panel of drug resistance.
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The DOTs Plus Strategy |
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Footnotes |
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