1373CHAPTER 178 Tuberculosis
organisms that, at the start of treatment, is noncavitary and/or sputum smear–negative). The same guidelines suggest that a 4-month
regimen consisting of isoniazid, rifampin, pyrazinamide, and ethambutol may be adequate for treatment of HIV-negative adults with
sputum smear–negative and culture-negative pulmonary TB (i.e.,
paucibacillary TB).
A continuation phase of once-weekly rifapentine and isoniazid
is effective in HIV-seronegative patients without cavitation on
CXR. In general, however, this regimen should be used with great
caution. Patients with cavitary pulmonary TB and delayed sputumculture conversion (i.e., those who remain culture-positive at
2 months) should be retested immediately for drug-resistant TB,
and a change of regimen should be considered. A full course of
6 months with four-drug therapy should be performed not including
interruptions of >4 weeks. In some developing countries where the
ability to ensure adherence to treatment is limited, a continuationphase regimen of daily isoniazid and ethambutol for 6 months
has been used in the past. This regimen is clearly associated with
a higher rate of relapse, treatment failure, and death, especially
among HIV-infected patients, and is no longer recommended by
the WHO. Several studies attempting to reduce treatment duration
to 4 months by using fluoroquinolones (with moxifloxacin replacing ethambutol or isoniazid, or gatifloxacin replacing ethambutol)
were conducted over the last decade. The main finding was that
shorter (4-month) fluoroquinolone-containing regimens are associated with significantly higher rates of relapse at 18 months than
the standard 6-month rifampin-containing regimen. In addition,
the studies showed no reduction in adverse events with the fluoroquinolone-containing regimen and no difference in all-cause and
TB-related mortality rates. Therefore, shortening of the treatment
duration to 4 months through the use of fluoroquinolones has
not been recommended. However, the recent Tuberculosis Trials
Consortium Study 31/AIDS Clinical Trials Group A5349 (Study
31/A5349) showed that a 4-month daily regimen that included
isoniazid, pyrazinamide, rifapentine at a daily dose of 1200 mg
and moxifloxacin at a daily dose of 400 mg was noninferior to
the standard 6-month regimen and had a similar adverse event
profile. In early 2021, this option was therefore considered by the
WHO as a possible alternative to the old standard provided that
rigorous antibacterial stewardship is ensured especially to prevent
fluoroquinolone resistance and that rifapentine becomes more
widely available. Alternative regimens for patients who exhibit drug
intolerance or adverse reactions are listed in Table 178-3. However,
severe side effects prompting discontinuation of any of the first-line
drugs and use of these alternative regimens are uncommon. To prevent isoniazid-related neuropathy, pyridoxine (10–25 mg/d) should
be added to the regimen given to persons at high risk of vitamin B6
deficiency (e.g., alcoholics; malnourished persons; pregnant and
lactating women; and patients with conditions such as chronic renal
failure, diabetes, and HIV infection, which are also associated with
neuropathy). Finally, to facilitate absorption of rifampin, the drug
should be taken on an empty stomach and without meals.
PATIENT CARE AND SUPPORT
Poor adherence to treatment is one of the most important impediments to cure. Moreover, the tubercle bacilli harbored by patients
who do not fully adhere to the prescribed regimen are likely to
become resistant to the drugs to which they are irregularly exposed.
Both patient- and provider-related factors may affect adherence.
Patient-related factors include a lack of belief that the illness is worth
the cost of adherence; the existence of concomitant medical conditions (notably alcohol or substance abuse); lack of social support; fear
of the stigma and discrimination associated with TB; and poverty,
with attendant joblessness and homelessness. Provider-related factors
that may prevent adherence include lack of support, education, and
encouragement of patients and inconvenient clinical services.
A variety of interventions to increase the chances of completion
of the months-long treatment course are available. First, a package of
social support interventions that are complementary and not mutually exclusive, consisting of educational, psychological, and material
goods and services, may enable people with TB to address hurdles
to treatment adherence. Health education and counseling on the disease’s seriousness and solutions and on the importance of treatment
adherence until cure should be provided to all patients at the start
of and throughout the course of TB therapy. Psychological support
(i.e., counseling sessions or peer-group support) can be particularly relevant in the context of the stigma and discrimination often
affecting people with TB and their families. Material support (e.g.,
food or financial support in forms such as meals, food baskets, food
supplements, food vouchers, transport subsidies, living allowances,
housing incentives, or financial bonuses) reduces indirect costs
incurred by patients or their attendants in accessing health services
and mitigates the consequences of income loss related to the disease.
Second, it is paramount that health services be arranged to meet
the needs and reasonable expectations of patients. Components of
optimal health services include a suitable geographic location, a
schedule responsive to patients’ needs, functional channels of communication between patients and their health care providers (e.g.,
TABLE 178-3 Recommended Antituberculosis Treatment Regimens
INITIAL PHASE CONTINUATION PHASE
INDICATION DURATION, MONTHS DRUGS DURATION, MONTHS DRUGS
New smear- or culture-positive cases 2 HRZEa,b 4 HRa,c
New culture-negative cases 2 HRZEa 4 HRa,d
Pregnancy 2 HREe 7 HR
Relapses and treatment defaultf Tailored according to rapid drug susceptibility testing
Failuresf Tailored according to rapid drug susceptibility testing
Resistance (or intolerance) to H Throughout (6) RZEQ
Resistance (or intolerance) to R Same as for MDR-TB; see below
MDR-TB (resistance to at least H + R) See Tables 178-4 and 178-5
XDR-TB See Table 178-4
Intolerance to Z 2 HRE 7 HR
a
All drugs should be given daily. b
A 4-month regimen of 8 weeks of once-daily rifapentine, isoniazid, pyrazinamide and moxifloxacin followed by 9 weeks of once-daily
rifapentine, isoniazid, and moxifloxacin is a possible alternative. c
A clinical trial showed that HIV-negative patients with noncavitary pulmonary tuberculosis who have
negative sputum AFB smears after the initial phase of treatment can be given once-weekly rifapentine/isoniazid in the continuation phase. However, this regimen is rarely
used. d
The American Thoracic Society, the Centers for Disease Control and Prevention, and the Infectious Diseases Society of America suggest that a 2-month continuation
phase could be used in HIV-seronegative patients with sputum smear–negative and culture-negative TB. e
The 6-month regimen with pyrazinamide can probably be used
safely during pregnancy and is recommended by the WHO and the International Union Against Tuberculosis and Lung Disease. If pyrazinamide is not included in the initial
treatment regimen, the minimal duration of therapy is 9 months. f
The availability of rapid molecular methods to identify drug resistance allows initiation of a proper regimen
at the start of treatment.
Abbreviations: E, ethambutol; H, isoniazid; MDR-TB, multidrug-resistant tuberculosis; Q, a quinolone antibiotic; R, rifampin; WHO, World Health Organization; XDR-TB,
extensively drug-resistant tuberculosis; Z, pyrazinamide.
1374 PART 5 Infectious Diseases
a telephone short-messaging system, audio/video call capability,
home or workplace visits), and a staff willing and competent to care
for people with TB, to address their concerns, and to base the care
they provide on sound ethical standards.
Third, it is crucial to offer the patient a suitable option for treatment administration that minimizes the chance of nonadherence.
Such options traditionally include unsupervised, self-administered
therapy; in-person directly observed therapy (DOT); and nondaily
DOT (e.g., supervision not for every dose but weekly or a few
times per week) at a location mutually agreed on by patient and
health care provider, with supervisory responsibility delegated to
a qualified person. Direct supervision of adherence is crucial in
view of the lack of tools to accurately predict adherence to selfadministered treatment and of the public health importance of TB.
The WHO, along with the ATS, the CDC, and the IDSA, states that
ideally all patients should have their therapy directly supervised,
especially during the initial phase, with proper social support
based on a patient-centered approach as described above. In several countries, personnel to supervise therapy are usually available
through TB control programs of local public health departments,
often involving members of the community who are accepted by the
patient and who have been properly trained and educated by health
workers to undertake the supervisory role. Direct supervision with
social support has been shown to significantly increase the proportion of patients completing treatment in all settings and to lessen
the chances of treatment failure, relapse, and default. In general,
community- or home-based DOT is recommended over health
facility–based DOT or unsupervised treatment; DOT administered
by trained lay providers or health care workers is recommended
over DOT administered by family members. Recently, comparison
of video-observed therapy (VOT) with in-person DOT has shown
similar outcomes. In a multicenter, analyst-blinded, randomized
controlled superiority trial of VOT through daily remote observation using a smartphone app versus DOT done 3−5 times weekly at
home, community, or clinic settings, VOT was superior to DOT in
ensuring scheduled observation of drug intake. Therefore, VOT can
replace DOT when Internet access is good and video communication technology (e.g., smartphones, tablets, computers) is available.
The system can be appropriately organized and operated by health
care providers and patients. Other digital health tools can facilitate
the monitoring of adherence, including digital medication monitors; these monitors can register when the pillbox is opened, with
options to emit audio signals or a short message to remind patients
to take medicines. These tools are customized to the needs and
preferences of the individual patient and the provider.
In addition to the above measures promoting adherence, provision of fixed-dose combination products that reduce the number of
tablets the patient needs to swallow is recommended over separate
drug formulations. Various fixed-dose combination products are
available (e.g., isoniazid/rifampin, isoniazid/rifampin/pyrazinamide,
and isoniazid/rifampin/pyrazinamide/ethambutol). Fixed-dose
combinations increase patient satisfaction and minimize the likelihood of prescription error or of development of drug resistance
resulting from monotherapy if a drug is out of stock or the patient
prefers one drug over others. In addition, these combinations facilitate programmatic management of procurement and supply. In the
past, the bioavailability of rifampin was found to be substandard in
some formulations of fixed-dose combinations. Medical regulatory
authorities should ensure that combination products are of good
quality; however, top standards for drug quality assurance are not
always operative, especially in limited-resource countries. Prescribers should be aware of this potential problem.
MONITORING TREATMENT RESPONSE AND DRUG TOXICITY
Bacteriologic evaluation through commercial liquid-culture systems
(or—when liquid-culture capacity is not yet available—through
smear microscopy) is essential in monitoring the response to TB
treatment. In addition, the patient’s weight should be monitored
regularly and the drug dosage adjusted with any significant weight
change. Patients with pulmonary disease should have their sputum
examined monthly until cultures become negative to allow early
detection of treatment failure. With the recommended 6-month
standard first-line regimen, >80% of drug-susceptible TB patients
will have negative sputum cultures at the end of the second month
of treatment. By the end of the third month, the sputum of virtually
all patients should be culture negative. In some patients, especially
those with extensive cavitary disease and large numbers of organisms, AFB smear conversion may lag behind culture conversion as
a result of the expectoration and microscopic visualization of dead
bacilli. Therefore, as capacity is built, smear microscopy should be
progressively abandoned as a monitoring tool in favor of liquid culture. As noted above, patients with cavitary disease in whom sputum
culture conversion does not occur by 2 months require immediate
testing or retesting for drug resistance. When a patient’s sputum
cultures or smears remain positive at ≥3 months despite good adherence, treatment failure caused by drug resistance is likely. The pattern of drug resistance should guide the choice of the best treatment
option (see below). A sputum specimen should be collected at the
end of treatment to document cure. In settings where mycobacterial
cultures are not yet available, monitoring by AFB smear examination should be undertaken at 2, 5, and 6 months. Bacteriologic
monitoring of patients with extrapulmonary TB is more difficult
and often is not feasible. In these cases, the response to treatment
must be assessed clinically with the help of medical imaging.
Monitoring of the response to chemotherapy by nucleic acid
amplification technology, such as the Xpert MTB/RIF assay, is not
suitable because these tests can produce positive results due to
nonviable bacilli. Likewise, serial chest radiographs are not recommended because radiographic changes may lag behind bacteriologic
response and are not highly sensitive. After the completion of treatment, neither sputum examination nor CXR is recommended for
routine follow-up purposes. However, a chest radiograph obtained
at the end of treatment may be useful for comparative purposes
should the patient develop symptoms of recurrent TB months or
years later. Patients should be instructed to report promptly for
medical assessment if they develop any such symptoms.
During treatment, patients should also be monitored for drug
toxicity. The most common adverse reaction of significance among
people treated for drug-susceptible TB is hepatitis. Patients should
be carefully educated about the signs and symptoms of drug-induced
hepatitis (e.g., dark urine, loss of appetite, nausea) and should be
instructed to discontinue treatment promptly and see their health
care provider if these manifestations occur. Although biochemical
monitoring is not routinely recommended, all adult patients should
undergo baseline assessment of liver function (e.g., measurement
of serum levels of hepatic aminotransferases and bilirubin). Older
patients, those with concomitant diseases, those with a history of
hepatic disease (especially hepatitis C), and those using alcohol
daily should be monitored especially closely (i.e., monthly), with
repeated measurements of aminotransferases, during the initial phase
of treatment. Up to 20% of patients have small increases (up to
three times the upper limit of normal) in serum levels of aspartate
aminotransferase that are not accompanied by symptoms and are of
no consequence. Suspension of treatment should be considered for
patients with symptomatic hepatitis, especially when accompanied by
at least a three-fold increase in serum levels of AST and/or ALT, and
for patients without symptoms of hepatic injury who have marked
(at least five-fold) elevations in serum levels of AST and/or ALT.
Drugs should be reintroduced one at a time after liver function has
returned to normal. Hypersensitivity reactions usually require the
discontinuation of all drugs and rechallenge to determine which agent
is the culprit. Because of the variety of regimens available, it usually
is not necessary—although it is possible—to desensitize patients.
Hyperuricemia and arthralgia caused by pyrazinamide can usually be
managed by the administration of acetylsalicylic acid; however, pyrazinamide treatment should be stopped if the patient develops gouty
arthritis. Individuals who develop autoimmune thrombocytopenia
secondary to rifampin therapy should not receive the drug thereafter.
Similarly, the occurrence of optic neuritis with ethambutol is an indication for permanent discontinuation of this drug. Other common
1375CHAPTER 178 Tuberculosis
manifestations of drug intolerance, such as pruritus and gastrointestinal upset, can generally be managed without the interruption of
therapy. Treatment with second-line agents for drug-resistant TB is
associated with a variety of adverse drug reactions that are more frequent and severe than in patients receiving first-line TB regimens (see
below). The likelihood of drug–drug interactions is also higher when
second-line regimens are used.
TREATMENT FAILURE AND RELAPSE
As stated above, treatment failure should be suspected when a
patient’s cultures (or sputum smears, when cultures are not available) remain positive after 3 months of treatment. In the management of such patients, it is imperative that the current isolate be
urgently retested (or tested for the first time if, for some reason,
rapid molecular susceptibility testing was not performed at the start
of treatment) for susceptibility to first-line agents and, if resistance
to rifampin is detected, to second-line agents as well. The treatment
approach should start with molecular testing for—at the least—
resistance to rifampin and isoniazid. Because results are expected
to become available within a few days, changes in the regimen
can be postponed until that time. However, if the patient’s clinical
condition is deteriorating rapidly, an earlier change in regimen may
be indicated. A cardinal rule in the latter situation is always to add
more than one drug, preferably two or three, at a time to a failing
regimen; in practice, starting an empirical regimen for MDR-TB
(see “Drug-Resistant TB,” below) is warranted. The patient may
continue to take isoniazid and rifampin along with these new agents
pending the results of susceptibility tests.
Patients who experience a recurrence after apparently successful
treatment (i.e., a relapse) are less likely to harbor drug-resistant
strains than are patients in whom treatment has failed. Acquired
resistance is uncommon among strains from patients in whom
relapse follows the proper completion of a standard 6-month regimen. The treatment decision depends on a general assessment of
the risk of drug resistance, the severity of the case, and the results
of rapid susceptibility testing. Patients whose treatment has been
interrupted and who have a high likelihood of MDR-TB should
receive an empirical MDR-TB regimen that includes second-line
agents (Table 178-3). Once drug susceptibility results are available,
the regimen can be adjusted accordingly.
DRUG-RESISTANT TB
Strains of M. tuberculosis resistant to individual drugs arise by
spontaneous point mutations in the mycobacterial genome
that occur at low but predictable rates (10–7–10–10 for the key
drugs). Resistance to rifampin is associated with mutations in the
rpoB gene in 95% of cases, that to isoniazid with mutations mainly
in the katG gene (50–95% of cases) and the inhA gene promoter
region (up to 45%), that to pyrazinamide in the pncA gene (up to
98%), that to ethambutol in the embB gene (50–65%), that to the
fluoroquinolones in the gyrA–gyrB genes (75–95%), and that to the
aminoglycosides mainly in the rrs gene (up to 80%); the C-12T
mutation is the most common mutation in the eis promoter region
associated with aminoglycoside resistance, especially in Eastern
European countries. Because there is no cross-resistance among the
commonly used classes of drugs, the probability that a strain will be
resistant to two drug classes is the product of the probabilities of
resistance to each drug class and thus is low. The development of
drug-resistant TB almost invariably follows monotherapy—i.e., the
failure of the health care provider to prescribe at least two drugs to
which tubercle bacilli are susceptible; of the patient to absorb or
take properly prescribed therapy; or of the bioavailability of
poor-quality drugs or preparations (e.g., due to crushing of tablets).
Drug-resistant TB may be either primary or acquired. In primary
drug resistance, the patient is infected from the start by a drugresistant strain. Acquired resistance develops in the infecting strain
during treatment. In North America, Western Europe, most of
Latin America, and the Persian Gulf states, rates of primary resistance are generally low and isoniazid resistance is most common. In
the United States, although rates of primary isoniazid resistance
have been stable at ~7–8%, the rate of primary MDR-TB has
declined from 2.5% in 1993 to <1% since 2000. As described above,
MDR-TB is an increasingly serious problem in some regions, especially in the countries of the former Soviet Union and some countries of Asia (Fig. 178-12). Even more serious is the occurrence of
MDR strains that are also resistant to additional second-line agents
used in treatment, such as the fluoroquinolones. Creation of
Percentage
of cases
0–2.9
3–5.9
6–11
12–17
18–24
≥25
No data
Not applicable
FIGURE 178-12 Percentage of new cases of multidrug-resistant/rifampin-resistant tuberculosis (TB) in all countries surveyed by the World Health Organization (WHO) Global
Drug Resistance Surveillance Project during 1994–2018. Figures are based on the most recent year for which data have been reported, which varies among countries. Data reported
before the year 2002 are not shown. (See disclaimer in Fig. 178-2. Reproduced with permission from Global Tuberculosis Report 2019. Geneva, World Health Organization; 2019.)
1376 PART 5 Infectious Diseases
drug-resistant TB can be prevented by adherence to the principles of
sound treatment: inclusion of at least two quality-assured, bactericidal drugs to which the organism is susceptible; use of effective
combination regimens; supervision of treatment with patient support; and verification that patients complete the prescribed course.
The use of fixed-dose combination products may prevent selective
drug intake and therefore possibly protect against the creation of
drug resistance. Transmission of drug-resistant strains can be prevented by the implementation of respiratory infection-control measures (see below) and by early detection of people with active TB
followed by immediate initiation of treatment with an effective
regimen.
Isoniazid-Resistant TB For the treatment of patients with
isoniazid-resistant disease, a combination of rifampin, ethambutol,
pyrazinamide, and levofloxacin for 6 months is recommended.
This fluoroquinolone-containing regimen should not be used until
rifampin resistance has been excluded by a reliable diagnostic test
to avoid inadvertent treatment of MDR-TB with an inadequate regimen. Ideally, a laboratory test for susceptibility should also be done
for the fluoroquinolones and pyrazinamide. If the fluoroquinolone
is contraindicated because of intolerance or resistance, the patient
can be given a 6-month regimen of rifampin, ethambutol, and pyrazinamide. Isoniazid probably does not contribute to a successful
outcome in these regimens but may be retained (also to facilitate
treatment with the four-drug fixed-dose formulation). Other drugs,
such as the injectable aminoglycosides, are unlikely to play a role in
the treatment of most isoniazid-resistant TB cases. However, they
may be considered in the presence of additional resistance (e.g., to
pyrazinamide or ethambutol) or of drug intolerance.
RR-, MDR-TB MDR-TB, in which bacilli are resistant to (at least)
isoniazid and rifampin, is more difficult to manage than is disease
caused by drug-susceptible organisms because these two bactericidal drugs are the most potent first-line agents available and
because associated resistance to other first-line drugs as well (e.g.,
ethambutol) is not uncommon. Treatment for RR-TB and MDR-TB
has traditionally been a topic of much debate, given its complexity, long duration, toxicity, and limited efficacy; the cost of most
second-line drugs; and the lack of randomized controlled clinical
trials to support combinations. Until recently, recommendations
were therefore based largely on low-quality evidence from observational studies and on best-practice consensus among experts.
Recent developments include the accrual of individual datasets
for patients treated worldwide, the release of findings from two
randomized controlled phase 3 clinical trials (the STREAM Stage 1
trial comparing a 9-month, shorter MDR-TB regimen with the previous optimized WHO background regimen; and Otsuka’s phase 3
trial 213 comparing the addition of the new drug delamanid to the
previous optimized WHO background regimen with the addition
of placebo), the publication of results of an open-label, single group
study enrolling highly drug-resistant cases on a regimen composed
of three oral drugs (bedaquiline, pretomanid, and linezolid), and
the assessment of programmatic data from South Africa on the
large-scale use of a shorter all-oral bedaquiline-containing regimen.
The assessment of this information resulted in an update of WHO
guidance for the treatment of MDR-TB and all other RR-TB cases
in which isoniazid resistance is absent or unknown.
As a result, two main approaches are now recommended by the
WHO to treat MDR/RR-TB: (1) an individualized longer regimen
of 18–20 months’ duration (or 15-17 months after culture conversion) consisting of an optimal combination of oral drugs chosen
according to a rational approach and using the WHO priority
grouping of medicines (Table 178-4); and (2) a shorter, all-oral,
bedaquiline-containing regimen of 9–12 months’ duration. While
these recommendations may change when new data indicate the
need, all-oral regimens are now the preferred options and the use
of either a shorter or a longer regimen depends on the assessment
of the severity of disease, knowledge of drug resistance pattern, and
history of previous treatment.
Longer MDR-TB Regimen In MDR/RR-TB patients where infecting strains have or are presumed to have additional resistance
(e.g., resistance to the fluoroquinolones), in those who have severe
pulmonary or extrapulmonary disease, or those who have been
treated previously with second-line drugs, a longer regimen is recommended. Table 178-4 shows the priority grouping of drugs recommended by the WHO and the approach to the design of a longer
regimen for both adults and children. As much as possible, the
regimen is composed of all group A agents and at least one group
B agent. The use of bedaquiline and linezolid is promoted, together
with a fluoroquinolone (levofloxacin or moxifloxacin), whenever
possible, in all patients. Clofazimine and cycloserine (group B) are
the two preferred options to be added to group A drugs. Group C
drugs can replace group A and B agents that cannot be used, and
the choice should be based on drug susceptibility testing, drug
resistance levels in the population, the patient’s history of previous
use of these drugs, and potential intolerance or toxicity. The injectable agents (e.g., amikacin, streptomycin, and the carbapenems)
are assigned a lower priority because of inconvenience of use and
the toxicity of aminoglycosides. A fully oral regimen is thus also
the first choice and most desirable option even for the most severe
cases who are ineligible for a shorter regimen. Nevertheless, when
injectables are necessary and DST supports their use, amikacin has
been found to be the most effective drug in this class, followed by
streptomycin, while kanamycin and capreomycin seem less effective, both having been associated with higher risks of failure and
relapse when compared with longer regimens in which other agents
were used instead. A treatment course of at least 18–20 months is
recommended, but duration may depend on the patient’s response.
Important considerations when treating MDR-TB patients include
the safety and effectiveness of bedaquiline use beyond 6 months.
Likewise, the ideal duration of use of linezolid, which is known to
be highly effective but also very frequently produces toxicity (e.g.,
peripheral and optic neuropathy, and bone marrow suppression), is
unclear. Additional considerations concern the use of pyrazinamide
and of the aminoglycosides amikacin and streptomycin, which is
now restricted to cases with proven susceptibility to those agents.
The role of delamanid in the treatment of MDR-TB remains to be
assessed, although, as stated earlier, data from the phase 3 clinical
trial of this agent as an addition to the longer regimen previously
recommended by the WHO did not demonstrate a higher rate of
treatment success than was obtained with the background regimen
plus placebo. Furthermore, evidence on the safety and effectiveness
of delamanid given for >6 months is presently incomplete.
Shorter MDR-TB Regimen In MDR/RR-TB patients with no extensive pulmonary disease or severe extrapulmonary disease, without
history of previous treatment with second-line drugs, and whose
TABLE 178-4 Groups of Drugs Recommended for Use in Longer
MDR-TB Regimens and Approach to the Design of a Longer Regimen
for Adults and Children
GROUP DRUG
Group A: Drugs to be prioritized and
included in all regimens, unless they
cannot be used
Levofloxacin or moxifloxacin
Bedaquiline
Linezolid
Group B: Drugs to be added in all
regimens, unless they cannot be used
Clofazimine
Cycloserine or terizidone
Group C: Drugs to be used to complete
the regimen and when drugs from
groups A and B cannot be used
Ethambutol
Delamanid
Pyrazinamide
Imipenem-cilastatin or meropenem
Amikacin or streptomycin
Ethionamide or prothionamide
p-Aminosalicylic acid
Source: Adapted from the World Health Organization, 2018.
1377CHAPTER 178 Tuberculosis
infecting strains are not resistant to the fluoroquinolones, a shorter,
all-oral, bedaquiline-containing regimen is recommended. Recent
observational programmatic data from South Africa, assessed by
WHO in 2019, showed that a fully oral regimen starting with
6 months of bedaquiline accompanied by 4−6 months of levofloxacin or moxifloxacin, ethionamide, ethambutol, pyrazinamide,
high-dose isoniazid (10–15 mg/kg per day), and clofazimine, and
followed by 5 months of levofloxacin (or moxifloxacin), clofazimine,
pyrazinamide and ethambutol, was associated with low toxicity and
better outcomes than the older, standardized, injectable-containing
regimen when used in patients, including the HIV-infected, with no
extensive pulmonary disease or severe extrapulmonary disease, fluoroquinolone resistance, or previous history of second-line drug use.
The WHO therefore now recommends the adoption of this regimen
and the progressive phasing-out of the previously recommended
injectable-containing shorter regimen. The WHO also recommends
that any modifications of a shorter regimen, where injectables are
replaced by drugs other than bedaquiline, should be tested under
operational research conditions and not adopted on a large programmatic scale until evidence shows their safety, tolerability, and efficacy.
The criteria used to define eligible patients are listed in
Table 178-5. Adults and children eligible for the shorter regimen
may still be offered the option of a new longer regimen if their completion of the full duration is adequately supported; with the longer
regimen, the likelihood of relapse-free cure could be increased, and
its administration is fully oral. As with any anti-TB regimen, the risk
of creating additional resistance is high if the regimen is used incorrectly (e.g., in someone with preexisting fluoroquinolone resistance).
As in past recommendations, informed consent should be sought
from patients treated with all MDR-TB regimens, and active TB drug
safety monitoring is recommended. Patients taking QT interval–
prolonging drugs (bedaquiline, delamanid, clofazimine, and fluoroquinolones) should be closely monitored, with electrocardiography
performed at the start of treatment and repeated during treatment;
patients with a QTc interval >500 ms or a history of ventricular
arrhythmias should not be given these drugs. Patients taking
amikacin should undergo serial audiometry to detect any hearing
loss early on. Incentives and other forms of support can encourage
patients not to interrupt treatment.
MDR-TB patients with additional resistance to fluoroquinolones
and other second-line medicines have fewer treatment options
and a poorer prognosis. However, the new longer regimen offers
more options for a reasonably effective and tolerable regimen. The
design of regimens for complex patterns of MDR-TB follows the
same principles outlined in Table 178-4 through the selection of
agents likely to be effective and tolerated. Observational studies
have shown that aggressive management in such patients, with early
drug susceptibility testing, use of a rational combination of at least
five effective drugs, strict adherence to directly observed therapy,
monthly bacteriologic monitoring, and intensive patient support,
may—besides interrupting transmission—increase the chances of
cure and avert death. For patients with localized disease and sufficient pulmonary reserve, lobectomy or wedge resection may be
considered as part of treatment. A novel regimen composed of
bedaquiline, the new nitroimidazole compound pretomanid, and
linezolid (BPaL) administered orally for 6 months has been tested by
the Global Alliance for TB Drug Development in South Africa in an
open-label, single-group study enrolling 109 patients with MDR-TB
caused by a strain with additional resistance to a fluoroquinolone
or a second-line injectable drug, or were intolerant of therapy, or in
whom treatment had failed. The cure rate was 90% after a 6-month
course of treatment; the main toxicity, due to linezolid, consisted of
peripheral neuropathy (81%) and myelosuppression (48%), which
were manageable with dose reduction or interruption of the drug.
Based on these findings, in August 2019 the FDA approved the
new drug pretomanid under the Limited Population Pathway for
Antibacterial and Antifungal Drugs (LPAD pathway) as part of a
three-drug, 6-month, all-oral regimen for the treatment of a population of patients with MDR-TB caused by a strain with additional
resistance to a fluoroquinolone or a second-line injectable drug, or
who were intolerant of therapy, or in whom treatment had failed.
Although approved by the FDA and proven as highly efficacious in
the only trial available, in late 2019 the WHO suggested that this
new 6−9 month regimen be used either under operational research
conditions until more information is available on safety and efficacy
or as a last resort in difficult-to-treat individual patients. A new,
dose-blinded study reported in 2021 suggested that BPaL regimens
where linezolid was used at reduced daily dose (from 1200 mg to
600 mg) and/or for a shorter period of time (from 6 to 2 months)
were safer. Another regimen being tested by the Global Alliance is
composed of bedaquiline, pretomanid, moxifloxacin, and pyrazinamide (BPaMZ). In a phase 2B trial, MDR-TB patients became
culture-negative within 8 weeks of treatment three times faster than
drug-sensitive TB patients treated with the standard regimen. The
BPaMZ regimen is now being tested for both MDR-TB and drugsusceptible TB, with the aim of reducing treatment duration to 6
months and 4 months, respectively. Results are expected in late 2021.
Because the management of MDR-TB is complicated by both
social and medical factors, care of seriously ill patients is ideally
provided in specialized centers or, in their absence, in the context
of programs with adequate resources and capacity, including community support. When patients are in stable condition, treatment
and care on an ambulatory basis at a decentralized health care facility should be prioritized as this approach may increase treatment
success and reduce loss to follow-up. This approach should not,
however, preclude hospitalization when it is necessary. Respiratory
infection-control measures should be observed throughout. As
part of a patient-centered approach, palliative and end-of-life care
should be provided as a priority when all recommended treatment
options have been exhausted.
HIV-ASSOCIATED TB
Several observational studies and randomized controlled trials have
shown that treatment of HIV-associated TB with anti-TB drugs and
simultaneous use of ART is associated with significant reductions in
mortality risk and AIDS-related events. Evidence from randomized
controlled trials shows that early initiation of ART during anti-TB
treatment is associated with a 34–68% reduction in mortality rates,
with especially good results in patients with CD4+ T-cell counts of
<50/μL. Therefore, the main aim in the management of HIV-associated TB is to initiate anti-TB treatment and to immediately consider
initiating or continuing ART. All HIV-infected TB patients, regardless of CD4+ T-cell count, are candidates for ART, which optimally
is initiated as soon as possible after the diagnosis of TB and with the
strong recommendation to start within the first 8 weeks of anti-TB
therapy; ART should be started within the first 2 weeks of TB treatment for profoundly immunosuppressed patients with CD4+ T-cell
counts of <50/μL. In general, the standard 6-month daily regimen
is equally efficacious in HIV-negative and HIV-positive patients
with drug-susceptible TB. However, in the uncommon situation
TABLE 178-5 Criteria for Offering a Shorter All-Oral Regimen
(9−11 Months) to Patients with Confirmed Multidrug- or
Rifampin-Resistant (MDR/RR) Tuberculosis (TB)
• Confirmed absence of resistance to or lack of suspicion of the ineffectiveness
of a drug in the shorter MDR-TB regimen (except for isoniazid resistance)
• No history of exposure to one or more second-line drugs used in the shorter
MDR-TB regimen (including bedaquiline) for >1 month
• Confirmed fluoroquinolone-susceptible disease
• No intolerance to drugs used in the shorter MDR-TB regimen or risk of toxicity
(e.g., drug–drug interactions)
• No pregnancy
• No extensive pulmonary disease
• No disseminated, meningeal, or central nervous system TB
• Availability of all drugs in the shorter MDR-TB regimen
Source: Adapted from the World Health Organization, 2019.
1378 PART 5 Infectious Diseases
where an HIV-infected patient cannot receive ART, prolongation
of the continuation phase of TB treatment by 3 months can be considered. As in any other TB patient, intermittent regimens should
not be used in HIV-infected people. As for any other adult living
with HIV (Chap. 202), first-line ART for TB patients consists of
two nucleoside reverse transcriptase inhibitors plus a nonnucleoside
reverse transcriptase inhibitor or an integrase or protease inhibitor. Recent guidelines have also considered a two-drug treatment
consisting of one nucleoside reverse transcriptase inhibitor plus an
integrase inhibitor. Although TB treatment modalities are similar
to those in HIV-negative patients, adverse drug reactions may be
more pronounced in HIV-infected patients. In this regard, three
important considerations are relevant: an increased frequency of
paradoxical reactions, interactions between ART components and
rifamycins, and development of rifampin monoresistance with intermittent treatment. IRIS—i.e., the exacerbation of symptoms and
signs of TB—has been described above. Rifampin, a potent inducer
of enzymes of the cytochrome P450 system, lowers serum levels
of many HIV protease inhibitors and some nonnucleoside reverse
transcriptase inhibitors—essential drugs used in ART. In such cases,
rifabutin, which has much less enzyme-inducing activity, has been
used in place of rifampin. However, dosage adjustments for rifabutin
and protease or integrase inhibitors are still being assessed. Several
clinical trials have found that patients with HIV/TB co-infection
whose degree of immunosuppression is advanced (e.g., CD4+ T-cell
counts of <100/μL) are prone to treatment failure and relapse with
rifampin-resistant organisms when treated with “highly intermittent” (i.e., once- or twice-weekly) rifamycin-containing regimens.
Consequently, it is now recommended that all TB patients who
are infected with HIV, like all other TB patients with rifampin-susceptible disease, receive a rifampin-containing regimen on a daily
basis. Because recommendations are frequently updated, consultation of the following websites is advised: www.who.int/hiv, www.who
.int/tb, www.cdc.gov/hiv, and www.cdc.gov/tb.
SPECIAL CLINICAL SITUATIONS
Although comparative clinical trials of treatment for extrapulmonary TB are limited, the available evidence indicates that most
forms of disease should be treated with a 6-month regimen recommended for patients with pulmonary disease. For TB meningitis,
the ATS, the CDC, and the IDSA recommend extension of the
continuation phase for 7–10 months. The WHO and the American Academy of Pediatrics recommend that children with bone
and joint TB, tuberculous meningitis, or miliary TB receive up to
12 months of treatment (2-month induction treatment followed
by 10-month consolidation treatment). Treatment for TB may be
complicated by underlying medical problems that require special
consideration. As a rule, patients with chronic renal failure should
not receive aminoglycosides and should receive ethambutol only if
serum drug levels can be monitored. Isoniazid, rifampin, and pyrazinamide may be given in the usual doses in cases of mild to moderate renal failure, but the dosages of isoniazid and pyrazinamide
should be reduced for all patients with severe renal failure except
those undergoing hemodialysis. Patients with hepatic disease pose
a special problem because of the hepatotoxicity of isoniazid, rifampin, and pyrazinamide. Patients with severe hepatic disease may be
treated with ethambutol, streptomycin, and possibly another drug
(e.g., a fluoroquinolone); if required, isoniazid and rifampin may
be administered under close supervision. The use of pyrazinamide
by patients with liver failure should be avoided. Silicotuberculosis
necessitates the extension of therapy by at least 2 months.
The regimen of choice for pregnant women (Table 178-3) is
9 months of treatment with isoniazid and rifampin supplemented
by ethambutol for the first 2 months. Although the WHO has
recommended routine use of pyrazinamide for pregnant women in
combination with isoniazid and rifampin, this drug has not been
recommended for pregnant women in the United States because of
insufficient data documenting its safety in pregnancy. Streptomycin
is contraindicated because it is known to cause eighth-cranial-nerve
damage in the fetus. The thioamides, bedaquiline, and delamanid
should also be avoided in the treatment of pregnant women with
MDR-TB. Treatment for TB is not a contraindication to breastfeeding; most of the drugs administered will be present in small
quantities in breast milk, albeit at concentrations far too low to provide any therapeutic or prophylactic benefit to the child.
Medical consultation on difficult-to-manage cases is provided by
the US CDC Regional Training and Medical Consultation Centers
(www.cdc.gov/tb/education/rtmc/).
PREVENTION
The primary way to prevent TB is to diagnose and isolate infectious
cases rapidly and to administer appropriate treatment until patients
are rendered noninfectious (usually 2–4 weeks after the start of proper
treatment) and the disease is cured. Additional strategies include BCG
vaccination and preventive treatment of persons with TB infection who
are at high risk of developing active disease.
■ BCG VACCINATION
Historically one of the most used vaccines in the history of medicine,
BCG was derived from an attenuated strain of M. bovis and was first
administered to humans in 1921. Many BCG vaccines are available
worldwide; all are derived from the original strain, but the vaccines vary
in efficacy, ranging from 80% to nil in randomized, placebo-controlled
trials. A similar range of efficacy was found in observational studies
(case-control, historic cohort, and cross-sectional) in areas where infants
are vaccinated at birth. These studies and a meta-analysis also found
higher rates of efficacy in the protection of infants and young children
from serious disseminated forms of childhood TB, such as tuberculous meningitis and miliary TB. BCG vaccine is safe and rarely causes
serious complications. The local tissue response begins 2–3 weeks after
vaccination, with scar formation and healing within 3 months. Side
effects—most commonly, ulceration at the vaccination site and regional
lymphadenitis—occur in 1–10% of vaccinated persons. Some vaccine
strains have caused osteomyelitis in ~1 case per million doses administered. Disseminated BCG infection (“BCGitis”) and death have occurred
in 1–10 cases per 10 million doses administered, although this problem
is restricted almost exclusively to persons with impaired immunity, such
as children with severe combined immunodeficiency syndrome or adults
with HIV infection. BCG vaccination induces TST reactivity, which
tends to wane with time. The presence or size of TST reactions after
vaccination does not predict the degree of protection afforded.
BCG vaccine is recommended for routine use at birth in countries
or among populations with high TB prevalence (Fig. 178-13). However, because of the low risk of transmission of TB in the United States
and other high-income countries, the variability in protection afforded
by BCG, and its impact on the TST, the vaccine is not recommended
for general use. HIV-infected adults and children should not receive
BCG vaccine. Moreover, infants whose HIV status is unknown but who
have signs and symptoms consistent with HIV infection or who are
born to HIV-infected mothers should not receive BCG.
Over the past decade, renewed research and development efforts
have been made toward a new TB vaccine, and several candidates have
been developed and tested. The MVA-85A was the first new TB vaccine
to be tested in a phase 2B proof-of-concept trial in infants in South
Africa. Results published in 2013 showed that MVA-85A was well tolerated and modestly immunogenic but did not confer significant protection against clinical TB or M. tuberculosis infection. A second, more
promising candidate vaccine, M72/AS01E
, a subunit vaccine pairing two
M. tuberculosis antigens (32A and 39A) with the adjuvant M72/AS01E
,
was recently tested in a randomized trial among 3575 patients with
M. tuberculosis infection to prevent development of active disease. TB
developed in 13 participants among those receiving the vaccine and in
26 among those receiving placebo with an estimated efficacy of 49.7%
at 36 months. Adverse events were not different in the two groups. This
vaccine is now being considered for further development.
As of the end of 2020, 14 candidate vaccines were in various stages
of clinical trials. They included whole-cell or mycobacterial whole-cell
1379CHAPTER 178 Tuberculosis
or lysates, viral vector vaccines, and adjuvant recombinant protein vaccines. Several challenges must be faced in the development of a TB vaccine. For instance, the lack of predictive animal models and protection
correlates renders trials long and expensive. Furthermore, the decision
about whether a candidate vaccine should be developed for prevention
of infection (preexposure) or prevention of reactivation (postexposure)
without an exact understanding of its precise mechanism of action is
complex. Therefore, introduction of a new vaccine on a large scale is
not likely in the near future. This step will require an intensified and
much larger investment in research and development.
■ TB PREVENTIVE TREATMENT (TPT)
It is estimated that 1.7 billion people—more than one-quarter of the
human population—have been infected with M. tuberculosis. Although
only a small fraction of these infections will progress toward active
disease in a lifetime, new active cases will continue to emerge from
this pool of infected individuals. Therefore, TPT (also called chemoprophylaxis or preventive chemotherapy, and previously referred to as
treatment of latent TB infection) is a fundamental intervention in TB
control and elimination strategies.
Infection can be tested using TST or IGRA, although these tests
just measure host immune response to TB antigens. Unfortunately, at
present, there is no gold-standard diagnostic test that can confirm true
infection (as opposed to immunologic memory of previous exposure)
or predict which infected individuals will develop active TB. As a
result, decisions to treat infection should include consideration of the
risk of progression in an individual. For skin testing, five tuberculin
units of polysorbate-stabilized PPD should be injected intradermally
into the volar surface of the forearm (i.e., the Mantoux method). Multipuncture tests are not recommended. Reactions are read at 48–72 h as
the transverse diameter (in millimeters) of induration; the diameter of
erythema is not considered. In some persons, TST reactivity wanes
with time but can be recalled by a second skin test administered
≥1 week after the first (i.e., two-step testing). For persons periodically
undergoing the TST, such as health care workers and individuals
admitted to long-term-care institutions, initial two-step testing may
preclude subsequent misclassification of those who have boosted
reactions as TST converters. The cutoff for a positive TST (and thus
for TPT) is related both to the probability that the reaction represents
true infection and to the likelihood that the individual, if truly infected,
will develop TB. Table 178-6 suggests possible conventional cutoff by
risk group. Thus, positive reactions for persons with HIV infection,
recent close contacts of infectious cases, organ transplant recipients,
Percentage
0–4.9
50–89
90–100
No data
Not applicable
FIGURE 178-13 Coverage of BCG vaccination in 2018. The target population of BCG coverage varies depending on national policies but is typically for the number of live
births in the year of reporting. (See disclaimer in Fig. 178-2. Reproduced with permission from Global Tuberculosis Report 2019. Geneva, World Health Organization; 2019.)
TABLE 178-6 Tuberculin Reaction Size and Cutoff for Tuberculosis
(TB) Preventive Treatment
RISK GROUP
TUBERCULIN REACTION
SIZE, mm
HIV-infected persons ≥5
Recent contacts of a patient with TB ≥5a
Organ transplant recipients ≥5
Persons with fibrotic lesions consistent with old TB
on chest radiography
≥5
Persons who are immunosuppressed—e.g., due to
the use of glucocorticoids or tumor necrosis factor
α inhibitors
≥5
Persons with high-risk medical conditionsb ≥5
Recent immigrants (≤5 years) from high-prevalence
countries
≥10
Injection drug users ≥10
Mycobacteriology laboratory personnel; residents
and employees of high-risk congregate settingsc
≥10
Children <5 years of age; children and adolescents
exposed to adults in high-risk categories
≥10
Low-risk personsd ≥15
a
Tuberculin-negative contacts, especially children, should receive prophylaxis for
2–3 months after contact ends and should then undergo repeat tuberculin skin
testing (TST). Those whose results remain negative should discontinue prophylaxis.
HIV-infected contacts should receive a full course of treatment regardless of TST
results. b
These conditions include silicosis and end-stage renal disease managed
by hemodialysis. c
These settings include correctional facilities, nursing homes,
homeless shelters, and hospitals and other health care facilities. d
Except for
employment purposes where longitudinal TST screening is anticipated, TST is
not indicated for these low-risk persons. A decision to treat should be based on
individual risk/benefit considerations.
Source: Adapted from Centers for Disease Control and Prevention: TB elimination—
treatment options for latent tuberculosis infection (2011). Available at http://www
.cdc.gov/tb/publications/factsheets/testing/skintestresults.pdf.
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