Liver disease People with alcoholic liver disease are at an increased risk of tuberculosis. The incidence of tuberculous peritonitis is particularly high in patients with cirrhosis of the liver. There are broadly two categories of treatment: A) Cirrhotic patients with essentially normal baseline liver function tests (Childs A Cirrhosis). Such patients may be treated with standard 4 drug regime for 2 months followed by 2 drugs for remaining 4 months (total 6-month treatment). B) Cirrhotic patients altered baseline liver function tests (Childs B & C). According to 2010 WHO guidelines: depending on the severity of the disease and degree of decompensation, the following regimen can be used, by altering the number of hepatotoxic drugs. One or two hepatotoxic drugs may be used in moderately severe disease (e.g., Childs B cirrhosis) whereas hepatotoxic drugs are completely avoided in decompensated Child C cirrhosis. • Two hepatotoxic drugs – 9 months of Isoniazid, Rifampin, and Ethambutol (until or unless isoniazid susceptibility is documented) – 2 months of Isoniazid, Rifampin, Ethambutol, and Streptomycin followed by 6 months of Isoniazid and Rifampin • One hepatotoxic drug – 2 months of Isoniazid, Ethambutol & Streptomycin followed by 10 months of Isoniazid and Ethambutol • No hepatotoxic drugs – 18–24 months of Streptomycin, Ethambutol, and quinolones. Patients with liver disease should have their liver function tests monitored regularly throughout TB treatment.
Pregnancy Pregnancy itself is not a risk factor for TB. Rifampicin makes
hormonal contraception less effective, so additional precautions need to be taken for
birth control while tuberculosis treatment. Untreated TB in pregnancy is associated with an increased risk of miscarriage and major fetal abnormality, and treatment of pregnant women. The US guidelines recommend omitting PZA when treating TB in pregnancy; the UK and WHO guidelines make no such recommendation, and PZA is commonly used in pregnancy. There is extensive experience with the treatment of pregnant women with TB and no toxic effect of PZA in pregnancy has ever been found. High doses of RMP (much higher than used in humans) causes neural tube defects in animals, but no such effect has ever been found in humans. There may be an increased risk of hepatitis in pregnancy and during the puerperium. It is prudent to advise all women of child-bearing age to avoid getting pregnant until TB treatment is completed.
Aminoglycosides (
STM,
capreomycin,
amikacin) should be used with caution in pregnancy, because they may cause deafness in the unborn child. The attending physician must weigh the benefits of treating the mother against the potential harm to the baby, and good outcomes have been reported in children whose mothers were treated with aminoglycosides. Experience in Peru shows that treatment for MDR-TB is not a reason to recommend termination of pregnancy, and that good outcomes are possible.
Kidney disease People with kidney failure have a 10 to 30-fold increase in risk of getting TB. People with kidney disease who are being given immunosuppressive medications or are being considered for transplant should be considered for treatment of
latent tuberculosis if appropriate.
Aminoglycosides (STM,
capreomycin, and
amikacin) should be avoided in patients with mild to severe kidney problems because of the increased risk of damage to the kidneys. If the use of aminoglycosides cannot be avoided (e.g., in treating drug-resistant TB) then serum levels must be closely monitored and the patient warned to report any side-effects (deafness in particular). If a person has end-stage kidney disease and has no useful remaining kidney function, then aminoglycosides can be used, but only if drug levels can be easily measured (often only amikacin levels can be measured). In mild kidney impairment, no change needs to be made in dosing any of the other drugs routinely used in the treatment of TB. In severe
chronic kidney disease (
GFR Definitions Multi-drug resistant tuberculosis (MDR-TB) is defined as TB that is resistant at least to INH and RMP. Isolates that are multi-resistant to any other combination of anti-TB drugs but not to INH and RMP are not classed as MDR-TB. As of October 2006, "Extensively drug-resistant tuberculosis" (XDR-TB) is defined as MDR-TB that is resistant to
quinolones and also to any one of
kanamycin,
capreomycin, or
amikacin. The old case definition of XDR-TB is MDR-TB that is also resistant to three or more of the six classes of second-line drugs. This definition should no longer be used, but is included here because many older publications refer to it. The principles of treatment for MDR-TB and for XDR-TB are the same. The main difference is that XDR-TB is associated with a much higher mortality rate than MDR-TB, because of a reduced number of effective treatment options.
Epidemiology of drug-resistant TB A 1997 survey of 35 countries found rates above 2% in about a third of the countries surveyed. The highest rates of drug-resistant TB were in the former USSR, the Baltic states, Argentina, India, and China, and was associated with poor or failing national Tuberculosis Control programmes. Likewise, the appearance of high rates of MDR-TB in New York city the early 1990s was associated with the dismantling of public health programmes by the
Reagan administration. Paul Farmer points out that the more expensive a treatment, the harder it is for poor countries to get. Farmer sees this as verging on denial of basic human rights. Africa is low in quality of treatment partly because many African cultures lack the 'concept of time' essential to the schedule of administration. MDR-TB can develop in the course of the treatment of fully sensitive TB and this is always the result of patients missing doses or failing to complete a course of treatment. Thankfully, MDR-TB strains appear to be less fit and less transmissible. It has been known of many years that INH-resistant TB is less virulent in guinea pigs, and the epidemiological evidence is that MDR strains of TB do not dominate naturally. A study in Los Angeles found that only 6% of cases of MDR-TB were clustered. This should not be a cause for complacency: it must be remembered that MDR-TB has a mortality rate comparable to lung cancer. It must also be remembered that people who have weakened immune systems (because of diseases such as HIV or because of drugs) are more susceptible to catching TB. Children represent a susceptible population with increasing rates of MDR and XDR-TB. Since diagnosis in pediatric patients is difficult, large number of cases are not properly reported. Cases of pediatric XDR-TB have been reported in most countries including the United States. In 2006 an outbreak of XDR-TB South Africa was first reported as a cluster of 53 patients in a rural hospital in
KwaZulu-Natal, with all but one dying. this was the largest group of linked cases ever found. Since the initial report in September 2006, cases have now been reported in most provinces in South Africa. As of 16 March 2007, there were 314 cases reported, with 215 deaths. It is clear that the spread of this strain of TB is closely associated with a high prevalence of HIV and poor infection control; in other countries where XDR-TB strains have arisen, drug-resistance has arisen from mismanagement of cases or poor patient compliance with drug treatment instead of being transmitted from person to person. This strain of TB does not respond to any of the drugs currently available in South Africa for first- or second-line treatment. It is now clear that the problem has been around for much longer than health department officials have suggested, and is far more extensive. By 23 November 2006, 303 cases of XDR-TB had been reported, of which 263 were in KwaZulu-Natal. Serious thought has been put to isolation procedures that may deny some patients their human rights, but which may be necessary to prevent further spread of this strain of TB.
Treatment of MDR-TB The treatment and prognosis of MDR-TB are much more akin to that for cancer than to that for infection. It has a mortality rate of up to 80%, which depends on a number of factors, including • How many drugs the organism is resistant to (the fewer the better), • How many drugs the patient is given (patients treated with five or more drugs do better), • Whether an injectable drug is given or not (it should be given for the first three months at least), • The expertise and experience of the physician responsible, • How co-operative the patient is with treatment (treatment is arduous and long, and requires persistence and determination on the part of the patient), • Whether the patient is HIV positive or not (HIV co-infection is associated with an increased mortality). Treatment courses are a minimum of 18 months and may last years; it may require surgery, though death rates remain high despite optimal treatment. That said, good outcomes are still possible. Treatment courses that are at least 18 months long and which have a directly observed component can increase cure rates to 69%. The treatment of MDR-TB must be undertaken by a physician experienced in the treatment of MDR-TB. Mortality and morbidity in patients treated in non-specialist centres is significantly elevated compared to those patients treated in specialist centres. In addition to the obvious risks (e.g., known exposure to a patient with MDR-TB), risk factors for MDR-TB include male sex, HIV infection, previous incarceration, failed TB treatment, failure to respond to standard TB treatment, and relapse following standard TB treatment. A large proportion of people with MDR-TB are unable to access treatment due to what
Paul Farmer describes as an "Outcome Gap". The majority of people struck with MDR-TB live in "resource-poor settings" and are denied treatment because international organizations have refused to make technologies available to countries who cannot afford to pay for treatment, the reason being that second line drugs are too expensive therefore treatment methods for MDR-TB are not sustainable in impoverished nations. Farmer argues that this is social injustice and we cannot allow people to die simply because they are faced with circumstances where they cannot afford "effective therapy". If the results of a gene probe (
rpoB) are known to be positive, then it is reasonable to omit RMP and to use SHEZ+
MXF+
cycloserine. The reason for maintaining the patient on INH despite the suspicion of MDR-TB is that INH is so potent in treating TB that it is foolish to omit it until there is microbiological proof that it is ineffective. There are also probes available for isoniazid-resistance (
katG and
mabA-inhA), but these are less widely available. When sensitivities are known and the isolate is confirmed as resistant to both INH and RMP, five drugs should be chosen in the following order (based on known sensitivities): • an
aminoglycoside (e.g.,
amikacin,
kanamycin) or polypeptide antibiotic (e.g.,
capreomycin) •
PZA •
EMB • a
fluoroquinolones:
moxifloxacin is preferred (
ciprofloxacin should no longer be used; •
rifabutin •
cycloserine • a
thioamide:
prothionamide or
ethionamide •
PAS • a
macrolide: e.g.,
clarithromycin •
linezolid • high-dose
INH (if low-level resistance) •
interferon-γ •
thioridazine •
meropenem and
clavulanic acid Drugs are placed nearer the top of the list because they are more effective and less toxic; drugs are placed nearer the bottom of the list because they are less effective or more toxic, or more difficult to obtain. Resistance to one drug within a class generally means resistance to all drugs within that class, but a notable exception is rifabutin: rifampicin-resistance does not always mean rifabutin-resistance and the laboratory should be asked to test for it. It is only possible to use one drug within each drug class. If it is difficult finding five drugs to treat then the clinician can request that high level INH-resistance be looked for. If the strain has only low level INH-resistance (resistance at 0.2
mg/L INH, but sensitive at 1.0 mg/L INH), then high dose INH can be used as part of the regimen. When counting drugs, PZA and interferon count as zero; that is to say, when adding PZA to a four drug regimen, you must still choose another drug to make five. It is not possible to use more than one injectable (STM, capreomycin, or amikacin), because the toxic effect of these drugs is additive: if possible, the aminoglycoside should be given daily for a minimum of three months (and perhaps thrice weekly thereafter). Ciprofloxacin should not be used in the treatment of tuberculosis if other fluoroquinolones are available. There is no intermittent regimen validated for use in MDR-TB, but clinical experience is that giving injectable drugs for five days a week (because there is no-one available to give the drug at weekends) does not seem to result in inferior results. Directly observed therapy certainly helps to improve outcomes in MDR-TB and should be considered an integral part of the treatment of MDR-TB. Response to treatment must be obtained by repeated sputum cultures (monthly if possible). Treatment for MDR-TB must be given for a minimum of 18 months and cannot be stopped until the patient has been culture-negative for a minimum of nine months. It is not unusual for patients with MDR-TB to be on treatment for two years or more. Patients with MDR-TB should be isolated in negative-pressure rooms, if possible. Patients with MDR-TB should not be accommodated on the same ward as
immunosuppressed patients (HIV infected patients, or patients on
immunosuppressive drugs). Careful monitoring of compliance with treatment is crucial to the management of MDR-TB (and some physicians insist on hospitalisation if only for this reason). Some physicians will insist that these patients are isolated until their sputum is smear negative, or even culture negative (which may take many months, or even years). Keeping these patients in hospital for weeks (or months) on end may be a practical or physical impossibility and the final decision depends on the clinical judgement of the physician treating that patient. The attending physician should make full use of therapeutic drug monitoring (particularly of the aminoglycosides) both to monitor compliance and to avoid toxic effects. Some supplements may be useful as adjuncts in the treatment of tuberculosis, but for the purposes of counting drugs for MDR-TB, they count as zero (if you already have four drugs in the regimen, it may be beneficial to add arginine, vitamin D, or both, but you still need another drug to make five). •
arginine, some clinical evidence (peanuts are a good source) •
Vitamin D (some in-vitro evidence; see
Vitamin D and tuberculosis treatment) The drugs listed below have been used in desperation and it is uncertain whether they are effective at all. They are used when it is not possible to find five drugs from the list above. •
imipenem •
co-amoxiclav •
clofazimine •
prochlorperazine •
metronidazole On 28 December 2012 the US
Food and Drug Administration (FDA) approved
bedaquiline (marketed as Sirturo by
Johnson & Johnson) to treat multi-drug resistant tuberculosis, the first new treatment in 40 years. Sirturo is to be used in a combination therapy for patients who have failed standard treatment and have no other options. Sirturo is an
adenosine triphosphate synthase (
ATP synthase) inhibitor. The follow drug is experimental compounds that are not commercially available, but which may be obtained from the manufacturer as part of a clinical trial or on a compassionate basis. Their efficacy and safety are unknown: •
Pretomanid (manufactured by
Novartis, developed in partnership with
TB Alliance) There is increasing evidence for the role of surgery (
lobectomy or
pneumonectomy) in the treatment of MDR-TB, although whether this is should be performed early or late is not yet clearly defined. :
See Modern surgical management ==Management in Asia==