1380 PART 5 Infectious Diseases
previously untreated persons whose chest radiograph shows fibrotic
lesions consistent with old TB, and persons receiving drugs that suppress the immune system are defined as an area of induration ≥5 mm
in diameter. A 10-mm cutoff is used to define positive reactions in most
other at-risk persons. For persons with a very low risk of developing TB
if infected, a cutoff of 15 mm is used. (Except for employment purposes
where longitudinal screening is anticipated, the TST is not indicated for
these low-risk persons.) A positive IGRA is based on the manufacturer’s
recommendations. Good clinical practice requires that, in addition to
test results, epidemiologic and clinical factors also guide the decision to
implement TPT and that active TB be definitively excluded before the
initiation of a prophylactic regimen. The WHO recommends systematic testing for infection and TPT for the following groups at high risk
of progression from infection to disease or of exposure and infection:
adults, adolescents and children older than 12 months living with HIV;
infants with HIV aged <12 months who are contacts of persons with TB;
all household contacts of patients with infectious pulmonary TB including children <5 years of age; patients with silicosis, patients starting antiTNF treatment, patients on dialysis, and patients preparing for organ or
hematologic transplantation. In addition, testing and TPT may be considered for persons living or working in at-risk institutional or crowded
settings, such as prisoners, health care workers, recent immigrants from
high-TB-burden countries, and homeless people who use drugs.
Some TST- and IGRA-negative individuals are also candidates for
TPT. Once an appropriate clinical evaluation has excluded active TB,
infants and children <5 years of age who were in contact with infectious cases should be offered TPT even in the absence of a positive
test for TB infection. HIV-infected persons >1 year of age who have
been exposed to an infectious TB patient should receive TPT regardless of the TST result. Any HIV-infected candidate for TPT must be
screened carefully to exclude active TB, which would necessitate full
disease treatment. The use of a clinical algorithm based on four signs/
symptoms (current cough, fever, weight loss, and night sweats) helps
to decide which HIV-infected person can start TPT. The absence of all
four symptoms tends to exclude active TB in people living with HIV.
The presence of one of these four manifestations, on the other hand,
warrants further investigation for active TB before TPT is started.
Although a test of TB infection is prudent before starting TPT, this
test is not an absolute requirement—given the logistical challenges—
among contacts aged <5 years and people living with HIV in highTB-incidence and low-resource settings.
Among people living with HIV and receiving ART, conversion of the
TST from negative to positive can occur during the first few months
of TPT. Conversions (from negative to positive) and reversions (from
positive to negative) are more common with IGRAs than with TSTs
among serially tested health care workers in the United States.
TPT in selected persons at risk aims at preventing active disease
and, in the absence of an immunizing vaccine, is a critical component
of TB elimination strategies. Potential candidates for TPT are listed in
Table 178-6. This intervention is based on the results of a large number
of randomized, placebo-controlled clinical trials demonstrating that
a 6- to 9-month course of isoniazid reduces the risk of active TB in
infected people by up to 90%. Analysis of available data indicated that
the optimal duration of treatment with this drug was ~9 months. In the
absence of reinfection, the protective effect is believed to be lifelong.
Clinical trials have shown that isoniazid reduces rates of TB among
TST-positive persons with HIV infection. Studies in HIV-infected
patients have also demonstrated the effectiveness of shorter TPT regimens containing a rifamycin. Several TPT regimens (Table 178-7) can
be used. The most widely used has been that based on isoniazid alone at
a daily dose of 5 mg/kg (up to 300 mg/d) for 9 months. On the basis of
cost–benefit analyses and concerns about feasibility, a 6-month period
of treatment at the same dose is considered adequate by the WHO.
An alternative regimen for adults is 4 months of daily rifampin, which
should also be effective against isoniazid-resistant strains. A 3-month
regimen of daily isoniazid and rifampin is used in some countries (e.g.,
the United Kingdom) for both adults and children who are known not
to have HIV infection. A previously recommended 2-month regimen
of rifampin and pyrazinamide has been associated with serious or even
fatal hepatotoxicity and is not recommended. The rifampin-containing
regimens should be considered for persons who are likely to have been
infected with an isoniazid-resistant strain. A clinical trial showed that
a regimen of isoniazid (900 mg) and rifapentine (900 mg), given once
weekly for 12 weeks, is as effective as the standard 9-month isoniazid
regimen. This regimen was associated with higher rates of treatment
completion (82% vs 69%) and less hepatotoxicity (0.4% vs 2.7%) than
isoniazid alone, although the rate of permanent discontinuation due to
an adverse event was higher (4.9% vs 3.7%).
Currently, the isoniazid–rifapentine regimen is not recommended
for children <2 years of age or pregnant women. Recently, an openlabel, randomized, phase 3 noninferiority trial has shown that among
HIV-infected persons, a 1-month regimen of daily rifapentine plus
isoniazid was noninferior to the 9-month daily isoniazid regimen and
ensured a higher treatment completion. As a result, the WHO has
included a 1-month regimen composed of daily isoniazid (300 mg)
and rifapentine (600 mg) among the available options for people aged
13 years or more. Rifampin and rifapentine are contraindicated in
HIV-infected individuals receiving protease inhibitors, most nonnucleoside reverse transcriptase inhibitors (e.g., nevirapine), and, for those
with chronic hepatitis B, tenofovir alafenamide. However, efavirenz
and tenofovir disoproxil can be used for simultaneous administration
with a rifamycin without dose adjustment. However, the dose of the
integrase inhibitor dolutegravir needs to be increased to 50 mg twice
daily when given together with rifampin, a dose that is usually well tolerated and gives equivalent efficacy in viral suppression and recovery
of CD4+ cell count compared with efavirenz. Administration of rifapentine with raltegravir was found to be safe and well tolerated. A recent
phase 1/2 trial of the 3-month regimen isoniazid plus rifapentine and
dolutegravir in adults with HIV reported good tolerance and viral
load suppression, no adverse events of grade >3, and did not indicate
that rifapentine reduced dolutegravir levels sufficiently to require dose
adjustment. Clinical trials to assess the efficacy of long-term isoniazid
administration (i.e., for at least 3 years) among people living with
HIV in high-TB-transmission settings have shown that this regimen
can be more effective than 9 months of isoniazid and is therefore
TABLE 178-7 Recommended Regimens and Drug Dosages for
Tuberculosis Preventive Treatmenta
REGIMEN DOSE ADVERSE EVENTS
Isoniazid alone for
6 or 9 months
Adults: 5 mg/kg (max,
300 mg) per day
Children <10 years of
age: 10 mg/kg per day
(range, 7−15 mg)
Drug-induced liver injury,
nausea, vomiting, abdominal
pain, skin rash, peripheral
neuropathy, dizziness,
drowsiness, seizure
Rifampin alone for
4 months
Adults: 10 mg/kg per day
Children <10 years of
age: 15 mg/kg (range,
10−20 mg) per day
Flulike syndrome, skin
rash, drug-induced liver
injury, anorexia, nausea,
abdominal pain, neutropenia,
thrombocytopenia, renal
reactions (e.g., acute tubular
necrosis and interstitial
nephritis)
Isoniazid plus
rifampin for
3 months
As above As above
Rifapentine plus
isoniazid for
3 months
Adults and children:
Isoniazid: 15 mg/kg
(900 mg) weekly
Rifapentine: 15–30 mg/kg
(900 mg) weekly
Hypersensitivity reactions,
petechial skin rash, druginduced liver injury
Anorexia, nausea, abdominal
pain
Hypotensive reactions
Rifapentine plus
isoniazid for
1 month
Age >13 years only:
Isoniazid 300 mg and
rifapentine 600 mg daily
(28 doses)
Essentially like those
of isoniazid alone with
neutropenia more common and
elevation in liver enzyme levels
and neuropathy less common
a
See text for full description of evidence on and limitations of these regimens.
Source: Reproduced with permission from World Health Organization.
1381CHAPTER 178 Tuberculosis
recommended under those circumstances. Studies looking at whether
briefer treatment with rifapentine-based regimens could achieve similar efficacies have been undertaken. Isoniazid should not be given to
persons with active liver disease. All isoniazid recipients at increased
risk of hepatotoxicity (e.g., those abusing alcohol daily and those with
a history of liver disease) should undergo baseline and then monthly
assessment of liver function; they should be carefully educated about
hepatitis and instructed to discontinue use of the drug immediately
should any symptoms develop. Moreover, these patients should be seen
and questioned monthly during therapy about adverse reactions and
should be given no more than a 1-month supply of drug at each visit.
Persons receiving high-dose isoniazid and who are at risk of vitamin
B6 (pyridoxine) deficiency, as listed above, should receive pyridoxine
to prevent peripheral neuropathy.
TPT among persons likely to have been infected by a multidrugresistant strain is a challenge because no clinical trial results are available to guide treatment. Close observation for early signs of disease
is one option. However, in selected high-risk household contacts of
patients with MDR-TB (e.g., children, recipients of immunosuppressive therapy), TPT may be considered on the basis of individualized
risk assessment and clinical criteria. In the absence of evidence of efficacy of any regimen, important factors in the decision to treat include
intensity of exposure, certainty about a source case, information on the
drug resistance pattern of the index case, and potential adverse events.
Confirmation of infection with available testing is generally required.
Drug selection should be based on the drug susceptibility profile of the
index case. One regimen recommended by the WHO is daily levofloxacin (750−1000 mg daily among adults) for 6 months.
It may be more difficult to ensure adherence to TPT than when
treating those with active TB. If family members of patients with active
TB are being treated, adherence and monitoring may be easier. When
feasible, supervised therapy may increase the likelihood of completion.
As in active cases, the provision of incentives may also be helpful.
Currently, no evidence shows that large-scale use of TPT leads to significant development of drug resistance. However, before TPT begins,
it is mandatory to carefully exclude active TB in order to prevent
undertreatment and promote development of drug resistance.
■ PRINCIPLES OF TB CONTROL
The highest priority in any TB control program is the prompt detection
of cases and the provision of treatment to all TB patients under proper
case-management conditions, including DOT and social support. In
addition, screening of high-risk groups, including immigrants from
high-prevalence countries, migrant workers, prisoners, homeless individuals, substance abusers, and HIV-seropositive persons, is recommended. TST- or IGRA-positive high-risk persons should receive TPT
as described above. Contact investigation is an important component
of efficient TB control. In the United States and other countries worldwide, a great deal of attention has been given to the transmission of
TB (particularly in association with HIV co-infection) in institutional
settings such as hospitals, homeless shelters, and prisons. Measures to
limit such transmission include respiratory isolation of persons with
suspected TB until they are proven to be noninfectious (at least by
sputum AFB smear negativity), proper ventilation in rooms of patients
with infectious TB, use of ultraviolet irradiation in areas of increased
risk of TB transmission, correct use of personal protective equipment,
and periodic screening of personnel who may come into contact with
known or unsuspected cases of TB. In the past, radiographic surveys,
especially those conducted with portable equipment and miniature
films, were advocated for case finding. Today, however, the prevalence
of TB in industrialized countries is sufficiently low that “mass miniature radiography” is not cost effective.
In high-prevalence countries, most TB control programs have made
remarkable progress in reducing morbidity and mortality since the
mid-1990s by adopting and implementing the standards and strategies
internationally promoted by the WHO. Between 2000 and 2018, more
than 60 million lives are estimated to have been saved. The essential
elements of good TB care and control were established in the mid1990s and consist of well-defined interventions that were the basis
of the “DOTS strategy”: early detection of cases and bacteriologic
confirmation of the diagnosis; administration of standardized shortcourse chemotherapy, with direct supervision to ensure adherence to
treatment and the provision of social support to patients; availability
of drugs of proven quality, with an effective supply and management
system; and a monitoring and evaluation system, including assessment
of treatment outcomes—e.g., cure, completion of treatment without
bacteriologic proof of cure, death, treatment failure, and default—in all
cases registered and notified as well as measurement of the impact of
control methods on classical TB indicators such as mortality, incidence,
prevalence, and drug resistance. In 2006, the WHO indicated that,
besides pursuing these essential elements that remain the fundamental
components of any control strategy, additional steps had to be undertaken in order to reach international TB control targets. These steps
included addressing HIV-associated TB and MDR-TB with additional
measures; operating in harmony with general health services; engaging
all care providers beyond the public providers; empowering people
with TB and their communities; and enabling and promoting research.
Evidence-based International Standards for Tuberculosis Care—
focused on diagnosis, treatment, and public health responsibilities—
were introduced for wide adoption by medical and professional
societies, academic institutions, and all practitioners worldwide.
Care and control of HIV-associated TB are particularly challenging
in poor countries because existing interventions require collaboration
between HIV/AIDS and TB programs as well as standard services. TB
programs must test every patient for HIV in order to provide access to
trimethoprim-sulfamethoxazole prophylaxis against common infections and ART. HIV/AIDS programs must regularly screen persons
living with HIV/AIDS for active TB, provide TPT, and ensure infection
control in settings where people living with HIV congregate.
Early and active case detection is considered an important intervention not only among persons living with HIV/AIDS but also
among other vulnerable populations, as it reduces transmission in a
community and provides early effective care. Additional measures are
indicated for the management of MDR-TB, RR-TB, and other forms
of drug-resistant TB; they include upgrades of laboratory capacity to
perform rapid DST and ensure surveillance of drug resistance; availability of drug regimens that are recommended for RR/MDR-TB, with
assured quality of drugs; and infection control measures in all settings
where patients with drug-resistant forms of TB may congregate. In
the new era of the United Nations Sustainable Development Goals
(2016–2030), the approach to TB control and care needs to evolve
further and become multisectoral and more holistic. Engagement
beyond dedicated programs and even the health sector is now essential. Therefore, the new “End TB” strategy promoted by the WHO
since 2016 builds on three pillars and relies on increased investments
and efforts by all governments, their national programs, and a multitude of partners within and beyond the health sector: (1) integrated,
patient-centered care and prevention; (2) bold policies and supportive
systems; and (3) intensified research and innovation. The first pillar
incorporates all technological innovations, such as early diagnostic
approaches (including universal DST and systematic screening of
identified, setting-specific, high-risk groups); well-designed treatment
regimens for all forms of TB; proper management of HIV-associated
TB and other comorbidities; and preventive treatment of persons at
high risk. The second pillar is fundamental and is normally beyond the
scope of dedicated programs, relying on policies forged by the highestlevel health and governmental authorities: availability of adequate
human and financial resources; engagement of civil organizations
and all relevant public and private providers to pursue proper care for
all patients and prevention for all people at risk; a policy of universal
health coverage (which, together with social protection, implies avoidance of catastrophic expenditures caused by TB among the poorest);
regulatory frameworks for case notifications, vital registration, quality
and rational use of medicines, and infection control; social protection
mechanisms as part of poverty alleviation strategies; and promotion
of interventions against the broader determinants of TB. Finally, the
third pillar of the new strategy emphasizes intensification of research
and development on new tools and interventions as well as optimal
1382 PART 5 Infectious Diseases
implementation and rapid adoption of new tools in endemic countries.
Besides specific clinical care and control interventions as described
in this chapter, elimination of TB in a society ultimately will require
control and mitigation of the multitude of direct risk factors (e.g., HIV
infection, smoking, alcohol abuse, diabetes) and socioeconomic determinants (e.g., extreme poverty, inadequate living conditions and poor
housing, malnutrition, indoor air pollution) with clearly implemented
policies within the health sector and other sectors linked to human
development and welfare.
■ FURTHER READING
Conradie F et al: Treatment of highly drug-resistant pulmonary
tuberculosis. N Engl J Med 382:893, 2020.
Dorman SE et al: Four-month rifapentine regimens with or without
moxifloxacin for tuberculosis. N Engl J Med 384:1705, 2021.
Getahun H et al: Latent Mycobacterium tuberculosis infection. N Engl
J Med 372:2127, 2015.
Nahid P et al: An Official American Thoracic Society/Centers for
Disease Control and Prevention/European Respiratory Society/
Infectious Diseases Society of America clinical practice guideline:
Treatment of drug-resistant tuberculosis. Am J Respir Crit Care Med
200:e93, 2019.
Nahid P et al: An Official American Thoracic Society/Centers for Disease Control and Prevention/Infectious Diseases Society of America
clinical practice guidelines: Treatment of drug-susceptible tuberculosis. Clin Infect Dis 63:853, 2016.
Pai M et al: Tuberculosis. Nat Rev Dis Primers 2:16076, 2016.
Swindells S et al: One month of rifapentine plus isoniazid to prevent
HIV-related tuberculosis. N Engl J Med 380:1001, 2019.
Tait DR et al: Final analysis of a trial of M72/AS01 vaccine to prevent
tuberculosis. N Engl J Med 381:2429, 2019.
Uplekar M et al: WHO’s new End TB strategy. Lancet 385:1799, 2015.
■ WEBSITES
World Health Organization: Global tuberculosis report
2020, Geneva, WHO, 2020. https://www.who.int/publications/i/
item/9789240013131
World Health Organization: Treatment of tuberculosis. Guidelines for treatment of drug-susceptible tuberculosis and patient
care. 2017 update. Geneva, WHO, 2017. https://apps.who.int/iris/
bitstream/handle/10665/255052/9789241550000-eng.pdf?sequence=1
World Health Organization: WHO Consolidated Guidelines on
Tuberculosis, Module 4: Treatment. Drug-Resistant Tuberculosis
Treatment. Geneva, WHO, 2020. https://www.who.int/publications/i/
item/9789240007048
World Health Organization: WHO consolidated guidelines on
tuberculosis. Module 3: Diagnosis. Rapid diagnostics for tuberculosis
detection. 2021 update. Geneva, WHO, 2021. https://www.who.int/
publications/i/item/9789240029415
Leprosy, also referred to as Hansen’s disease, is a chronic infectious disease caused by Mycobacterium leprae. The clinical manifestations are
largely confined to the skin, peripheral nervous system, eyes, and upper
respiratory tract. The differing immune responses to M. leprae result in
a spectrum of disease ranging from tuberculoid to lepromatous leprosy.
M. leprae has a predilection for peripheral nerves, and immunologically mediated reactional states can cause nerve damage to the face,
arms, and legs; this damage often results in disability, which in turn
can lead to stigma and social exclusion. The physical disfigurement
179 Leprosy
Jan H. Richardus, Hemanta K. Kar,
Zoica Bakirtzief, Wim H. van Brakel
that accompanies leprosy has left marks on society that have endured
long after the disease’s disappearance in many countries. In everyday
language, leprosy has become a metaphor for a horrible condition
that warrants social exclusion. Leprosy is a neglected disease and is
often thought no longer to exist. However, 202,185 new cases from
150 countries were reported in 2019. A general lack of awareness
among both the public and medical practitioners often delays diagnosis and treatment and thus results in irreversible impairments. Early
diagnosis and treatment of leprosy and leprosy reactions can cure the
disease and prevent most chronic complications.
■ ETIOLOGY
M. leprae is an obligate, intracellular, acid-fast staining, rod-shaped
bacterium, measuring 1–8 μm in length and 0.3 μm in diameter.
M. leprae mostly appears irregularly stained and fragmented or granular, in which case the organism is usually considered to be dead. The
few bacteria that are brightly and uniformly stained are thought to be
solid, viable bacilli. The morphologic index is a measure of uniformly
stained solid bacilli on slit-skin smear examination and is calculated
as the percentage of viable bacilli among the total number of bacilli
counted under oil-immersion microscopy. On slit-skin smear examination at the lepromatous end of the disease spectrum, M. leprae is predominantly found in clumps or globi within macrophages (lepra cells).
Inside these cells, M. leprae multiplies in unrestricted fashion, and hundreds of bacilli may be present; the organisms are arranged in parallel
arrays placed side by side as a result of the presence of surface lipids
(glial substances). The bacteriologic index is a logarithmic-scaled measure of the density of bacilli of all forms found in the dermis upon slitskin smear examination, varying from 0 to 6+ (with or without globi)
from the tuberculoid to the lepromatous end of the disease spectrum.
The bacteriological index falls an average of 1 log unit per year with
multidrug therapy. M. leprae infects mainly macrophages and Schwann
cells. It has never been grown in artificial media. Reproduction occurs
by binary fission, and the organism grows slowly (over 12–14 days)
in the footpads of mice. The temperature required for survival and
proliferation—between 27°C and 30°C—explains the greater impact of
the disease on surface areas such as the skin, peripheral nerves, testicles, and upper airways, with less inner visceral involvement. M. leprae
remains viable for 9 days in the environment.
Ultrastructural Characteristics of M. leprae Electron microscopy reveals that M. leprae has a cytoplasm, plasma membrane, cell
wall, and capsule. The cytoplasm contains structures common in
gram-positive microorganisms. The plasma membrane has a permeable lipid bilayer containing interacting proteins—the protein
surface antigens. Similar to that of other mycobacteria, M. leprae’s
cell wall, which is attached to the plasma membrane, is composed of
peptidoglycans bound to branched-chain polysaccharides; these peptidoglycans are arabinogalactans, which support mycolic acids, and
lipoarabinomannan (LAM). The capsule—the outermost structure—
contains lipids, particularly phthiocerol dimycocerosate and phenolic
glycolipid (PGL-1), which has a trisaccharide bound to lipid by a
molecule of phenol. Because this trisaccharide is antigenically specific
for M. leprae, its detection is helpful in serologic diagnosis of leprosy.
Genome of M. leprae Comparative analysis of the genomics
of single-nucleotide polymorphisms indicates that four distinct
strains of M. leprae originated in East Africa or Central Asia.
A mutation spread to Europe and subsequently underwent two separate mutations that were then followed by spread to West Africa and
the Americas. The genome of M. leprae is circular. Its estimated molecular mass is 2.2 × 109
Da, with 3,268,203 base pairs and a guanine-pluscytosine content of 57.8%.
Culture Difficulties Compared to the genome of Mycobacterium
tuberculosis, that of M. leprae underwent reductive evolution, resulting
in a smaller genome rich in inactive or entirely deleted genes. This
reductive evolution, gene decay, and genome downsizing all may
explain the unusually long generation time and may account for the
inability to culture the leprosy bacillus in artificial media. As a result,
1383CHAPTER 179 Leprosy
prevalence, which would include existing cases that have not yet been
detected. The two factors that determine the registered prevalence are
the new case detection rate and the duration of treatment; changes in
either factor will affect the registered prevalence.
The WHO leprosy disability grading system scores patients according to the presence of disabilities of the eyes, hands, and feet. For the
hands and feet, grade 0 means no anesthesia and no visible impairment; grade 1 signifies anesthesia but no visible impairment; and grade
2 indicates visible impairment. For the eyes, grade 0 signifies no eye
problems due to leprosy and no evidence of visual loss; grade 1 signifies
eye problems due to leprosy without severe effects on vision; and grade
2 indicates severe visual impairment (vision score worse than 6/60;
inability to count fingers at 6 meters) and also includes lagophthalmos,
iridocyclitis, and corneal opacities. The sum score for these six body
sites is called the Eye-Hand-Foot (EHF) score and is used as an overall
indicator of the impairment status of a person with leprosy. Leprosyrelated grade 2 disability is usually reported as the proportion of people
with such disability at any site among patients newly diagnosed with
leprosy in a specific year.
The global trend in new case detection since 1985 is presented
in Fig. 179-1. The trend was remarkably static up to the year 2001,
with a peak around the year 2000; fell dramatically between 2001
and 2005; and has leveled off since 2006. The most important factor
contributing to the fast downward trend was the decline in leprosy
control activities following the declaration by the WHO in 2000 that
leprosy was eliminated as a “public health problem.” Elimination was
defined as a prevalence of <1 case per 10,000 population at the global
level. The attainment of this target was a great achievement but led
many to believe that the problem of leprosy was solved altogether. This
misunderstanding in turn led to reduced political commitment to leprosy control programs and facilities, with consequent downsizing and
decreased funding. The stabilization of the new case detection rate at
just over 200,000 cases annually since 2006 indicates that transmission
of M. leprae is continuing unabated, posing an enormous challenge in
leprosy control.
Sex, Age, and Geographic Distribution Approximately 40%
of all reported leprosy patients are women, but the low proportion in
some countries raises concerns about underdiagnosis in women due to
poor access to health services, illiteracy, low status, and other cultural
factors. The age-specific incidence often shows a bimodal pattern, with
peaks in the teenage years and in adulthood. Around 8% of all newly
detected cases are found in children (<15 years of age), a measure that
is often taken as an indicator of continued (recent) transmission. Leprosy is rare among children <5 years of age. Around 5% of all patients
have a grade 2 disability.
propagation of M. leprae has been restricted to animal models, including the armadillo and normal, athymic, and gene-knockout mice.
These systems have provided the basic resources for genetic, metabolic,
and antigenic studies of the bacillus. Growth of M. leprae in mouse
footpads also provides a tool for assessing the viability of the bacteria
and testing the drug susceptibility of clinical isolates.
Immunologic Properties of M. leprae M. leprae induces both
humoral and cell-mediated immune responses. The immunogenic
components of M. leprae include polysaccharides and proteins. Polysaccharide components induce mainly a humoral immune response,
whereas protein components induce both humoral and cell-mediated
immune responses. The immunogens in M. leprae form two distinct
groups: cytoplasmic antigens and antigens from the mycobacterial cell.
As mentioned above, a species-specific phenolic glycolipid, PGL-1,
has been identified in M. leprae. Other varieties of M. leprae antigens
identified with monoclonal antibodies include antigens of 18, 28, 7,
14, 36, 65, and 70 kDa that may possibly induce an immune response.
Mycobacterium lepromatosis In 2008, a new mycobacterial species,
M. lepromatosis, was isolated from patients with a special type of diffuse lepromatous leprosy known as diffuse leprosy of Lucio and Latapí.
This clinical variety of leprosy is found mainly in Mexico and Central
America. M. lepromatosis is very similar to M. leprae microbiologically
and clinically. Microbiologically, both species are acid-fast and noncultivable and preferably infect skin and peripheral nerves. Clinically,
differentiation of M. lepromatosis from M. leprae in individual patients
is not diagnostically necessary since both organisms respond well to
the same antimycobacterial regimens.
■ EPIDEMIOLOGY
Incidence, Prevalence, and Disability The true incidence
of leprosy is difficult to establish because the figure is very low and
because the initial signs and symptoms are often insidious, and thus
not all cases are detected as they occur. In 2019, as stated earlier,
202,185 new cases were reported to the World Health Organization
(WHO) from 150 countries. New case detection per year is commonly
used as a proxy for incidence, but operational factors, such as the intensity of case detection, the use of surveys, the use of contact tracing, the
level of community awareness, and the quality and availability of health
care, have a profound effect on case detection rates. In nonendemic
countries around the world, leprosy is often misdiagnosed simply
because it is not considered.
The registered prevalence of leprosy is defined as the number of
patients receiving treatment at a point in time (usually at the end of a
calendar year). The registered prevalence is a proxy measure for true
1985
0
100,000
200,000
300,000
400,000
500,000
1986
1987
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
2016
2017
2018
2019
600,000
700,000
800,000
900,000
FIGURE 179-1 Global trend in leprosy new-case detection, 1985–2019.
1384 PART 5 Infectious Diseases
There are large variations among world regions and countries in
new case detection rates. Approximately 80% of global new case detection is reported from India, Brazil, and Indonesia. There are also distinct geographic variations within countries, with differences between
urban and rural communities and clustering of cases at the village or
neighborhood level. Geographic variations can be due to differences
in health service provision, socioeconomic development, isolation,
and poverty. Figure 179-2 depicts the geographic distribution of new
leprosy cases in 2018.
Transmission Understanding of the transmission of M. leprae is
limited. The existing evidence is largely circumstantial because of the
long incubation period from exposure to disease, the inability to culture
M. leprae, and the difficulty of diagnosing both infection and early disease. M. leprae organisms can be shed in large numbers from the mouth
and nose of patients with untreated multibacillary leprosy (droplet
infection) and sometimes from damaged skin, but it is unclear whether
patients with paucibacillary leprosy can spread the bacillus. There is evidence for transmission between humans and—in southern U.S. states—
for zoonotic transmission through wild armadillos. The main route of
entry into the body is assumed to be the respiratory tract, but in patients
with wounds or tattoos, transmission through the skin also is possible.
Reservoirs of Infection It is assumed that humans are the main
reservoir of infection for M. leprae. The armadillo is also a reservoir
for human infection. Certain species of monkeys and red squirrels
are infected with M. leprae in the wild, but there is no evidence of
transmission to humans through contact with these animals. Evidence
is weak for the potential of water and soil as environmental sources of
M. leprae. The higher incidence rate of leprosy among household contacts of multibacillary cases than among those of paucibacillary cases
suggests that multibacillary cases represent an important reservoir for
undetected and untreated cases in the community; that is, a prolonged
period between the onset of signs of leprosy and treatment due to a
delay in diagnosis and initiation of multidrug therapy increases exposure in the community. Persons with subclinical leprosy are likely to
be a main source of infection, given that multidrug therapy for clinical
leprosy apparently has not made an impact on transmission.
Incubation Period, the Role of Contacts, and Genetic
Susceptibility The incubation period of leprosy is estimated to
range from 2 to ≥10 years. The incubation period for multibacillary
leprosy appears to be longer (5 to ≥10 years) than that for paucibacillary leprosy (~2–5 years). Poverty-associated factors such as low level
of education, poor hygiene, and food shortages have been identified as
risk factors for leprosy, but the most important risk factors are associated with intimacy and duration of contact with a leprosy patient,
in particular with an index case with multibacillary leprosy, and the
intensity of contact with and physical distance from the index patient.
Increasing evidence from studies in twins and from observational studies supports host genetic susceptibility to leprosy. Ongoing studies are
exploring the mechanism underlying genetic susceptibility to leprosy
and its clinical manifestations.
■ PATHOGENESIS
Whatever the route of M. leprae’s entry into the human body, the
pathogenic process usually starts in the peripheral nerves. Once bacilli
are engulfed by Schwann cells, the histopathologic changes in nerve
and skin—and thus the type of leprosy that develops—depend on the
immunologic resistance of the person infected, in particular on the
cell-mediated immune (CMI) response to the bacillus and its antigens.
Ridley-Jopling Classification of Leprosy In 1962, Ridley and
Jopling described five overlapping categories of leprosy: tuberculoid
(TT), borderline tuberculoid (BT), mid-borderline (BB), borderline
lepromatous (BL), and lepromatous (LL). An early clinical manifestation is recognized and referred to as indeterminate leprosy (IL).
Immunologic resistance is strong at the tuberculoid end of the spectrum, gradually diminishes through the borderline spectrum, and is
weakest in lepromatous leprosy. The LL and TT types of leprosy are
relatively stable, with little or no change in clinical disease expression
over time, while the BL, BB, and BT types are unstable both clinically
and immunologically. Further distinction indicates that subpolar types
of TT and LL leprosy (TTs and LLs) are less stable than polar types
(TTp and LLp). The immune reaction depends on predisposing genetic
factors and the extent of exposure to M. leprae. The host tissue’s reaction and related damage are largely due to delayed hypersensitivity. In
response to the presence of M. leprae, a granuloma is formed either
by macrophage–lymphocyte interaction when there is immunity or
otherwise by macrophages only. The formation of a granuloma is preceded by a stage of infiltration by lymphocytes alone, as is seen in IL.
Because of the strong immune response toward the tuberculoid end of
0 6 1,500 3,000 ,000 Kilometers
New leprosy cases–2018–
0
1–10
11–100
101–1000
1001–10,000
>10,000
No data
FIGURE 179-2 Geographic distribution of new leprosy cases, 2018. (Reproduced with permission from Global leprosy update, 2018: moving towards a leprosy-free world.
Wkly Epidemiol Rec 35/36:389, 2019.)
1385CHAPTER 179 Leprosy
the spectrum, macrophages, along with many lymphocytes, become
fixed epithelioid cells, and groups of these cells become giant cells. The
tuberculoid granuloma leads to nerve destruction resulting in anesthesia and muscle weakness. The cellular response is less focal and less
destructive in the borderline portion of the spectrum; consequently,
there is less damage to nerves and few bacilli are present. In BL leprosy,
there are macrophage granulomas along with lymphocytes, but little
nerve damage and more bacilli. In LL leprosy, bacilli multiply within
Schwann cells and perineural cells. Liberated bacilli from these cells are
engulfed by histiocytes, becoming wandering macrophages and traveling throughout the body to other nerves and tissues via blood, lymph,
and tissue fluids. In addition, there are diffuse lepromas in LL leprosy
that consist of histiocytes and/or macrophages, with very few lymphocytes and plasma cells. The bacilli are packed within macrophages
called globi and outside macrophages either singly or in small groups.
WHO Simplified Clinical Classification of Leprosy RidleyJopling classification requires clinical and pathologic expertise that
does not exist in many settings. The WHO has therefore introduced
a simplified classification system based on slit-skin smear: patients
with negative slit-skin smear results at all body sites are classified as
having paucibacillary leprosy, whereas patients with positive smears at
any body site are classified as having multibacillary leprosy. However,
because slit-skin smear facilities are not available or dependable in
many countries, most leprosy control programs use clinical criteria
only for classifying leprosy and deciding on the appropriate treatment
regimen for individual patients. In this circumstance, paucibacillary leprosy is defined as one to five skin lesions and no or only one
involved peripheral nerve, while multibacillary leprosy is defined as six
or more skin lesions and/or more than one involved peripheral nerve.
■ CLINICAL MANIFESTATIONS
Leprosy is a disease affecting mainly the skin, cutaneous and peripheral
nerves, mucous membranes, and, less commonly, other sites such as
joints, lymph nodes, eyes, and testes. Other systemic manifestations
may occur, particularly in BL and LL disease, with or without leprosy
reactions. Most dermal and cutaneous nerves feeding skin lesions are
affected—e.g., the supraorbital, great auricular, radial cutaneous, infrapatellar, superficial fibular, and sural nerves and the cutaneous nerves
of the thigh. The peripheral nerves involved include the ulnar, median,
radial (in upper limbs), lateral popliteal, and posterior tibial (in lower
limbs). The cranial nerves commonly involved are the trigeminal and
facial.
Indeterminate Leprosy (IL) This early clinical type manifests
as one or a few hypopigmented or faintly erythematous, ill-defined
to well-defined macular lesions measuring 1–5 cm in diameter. These
lesions invariably occur on the external aspects of the limbs, buttocks,
and face, with mild to moderate impairment of touch and/or thermal
sensations. There is no thickening of the corresponding cutaneous
and peripheral nerves. IL is often, but not always, the first clinical
sign of leprosy. This type either heals spontaneously or progresses to
a determinate form of the disease (TT, BT, BB, BL, or LL), depending
on CMI status.
Tuberculoid (TT) Leprosy TT leprosy (Fig. 179-3) presents
either as a well-defined, hypopigmented macule or as a raised, erythematous/brown/copper-colored plaque with a well-defined edge. The
lesions may be found on any part of the skin and are characterized
by complete loss of fine touch and temperature sensations over their
surface. Skin lesions are single or few (up to three) in number and can
be of any size, but they seldom measure >10 cm in diameter. In plaquetype lesions, the raised clear-cut edge often slopes inward to a flattened
and sometimes hypopigmented central area, acquiring an annular configuration. The skin surface of both macular and plaque lesions is dry,
hairless, and anesthetic because of destruction of underlying superficial
cutaneous nerves. Larger corresponding cutaneous nerves are thickened in a limited number of cases. On the face, sensory impairment
may be difficult to demonstrate because of the generous and bilateral
supply of sensory nerve endings. Autonomic nerve damage within the
lesion is responsible for surface dryness and loss of sweating over the
lesion. A solitary peripheral-nerve trunk in the vicinity of a lesion may
be thickened, with sensory loss of the area supplied and with or without motor disfigurement. On slit-skin smear examination, no acid-fast
bacilli (AFB) are normally found. The lepromin skin test is strongly
positive, signifying good host CMI status.
Borderline Tuberculoid (BT) Leprosy BT leprosy (Fig. 179-4)
is characterized by either macular or plaque-type lesions numbering
three to nine or more and asymmetrically located on any part of the
body, with variable sizes and contours. The margins of the lesions range
from poorly defined to well defined; sometimes both forms of margin
are seen in one lesion. There may be smaller satellite lesions around
a larger one, especially on sides where the margin is less defined; this
characteristic indicates downgrading of the lesion from TT to BT
leprosy. The edges of plaque lesions may slope outward in contrast to
TT lesions, which slope inward; plaques may gradually fade outward
and eventually blend into normal-looking skin. Loss of sensation is
less intense than it is in TT lesions and dryness on the surface less
conspicuous. Several peripheral nerves are likely to be enlarged in an
asymmetrical pattern, with sensory and motor deficits. One of the
most striking features of BT leprosy is susceptibility to a type 1 leprosy
reaction (T1R; see below) that exacerbates skin lesions and/or peripheral nerves. If not diagnosed and treated early, disease in these patients
tends to downgrade across the spectrum to BB, BL, or LLs leprosy, with
an increasing bacteriologic index and a regressed CMI response causing nerve damage along the way. Slit-skin smears show bacteriologic
indices varying from negative to 1+.
FIGURE 179-3 Tuberculoid (TT) leprosy. Hypopigmented macular lesion with a welldefined edge and loss of fine-touch sensation. (From Dr. H. K. Kar, with permission.)
FIGURE 179-4 Borderline tuberculoid (BT) leprosy. Macular lesion with irregular,
moderately defined edge and satellite lesion, with loss of sensation. (From Dr. W. H.
van Brakel, with permission from NLR.)
1386 PART 5 Infectious Diseases
FIGURE 179-5 Borderline lepromatous (BL) leprosy. Numerous diffusely infiltrated
erythematous and hypopigmented macules, downgrading from borderline
tuberculoid to lepromatous leprosy. (From Dr. C. L. M. van Hees, Department of
Dermatology, Erasmus MC, University Medical Center, Rotterdam, the Netherlands,
with permission.)
FIGURE 179-6 Lepromatous (LL) leprosy. Multiple nodules on ears and face and loss
of eyebrows. (From Dr. K. Mponda, Department of Dermatology, Queen Elisabeth
Central Hospital, Blantyre, Malawi, with permission.)
Mid-Borderline (BB) Leprosy This form of leprosy is unstable.
Many cases downgrade toward BL and LLs disease, especially if not
treated. There are multiple plaque lesions and, not infrequently, macular lesions; the lesions are of various shapes and sizes, are bilateral, and
usually occur in a more or less symmetrical distribution. In annular
lesions, the inner edge is well demarcated and “punched out,” and the
outer edge is ill defined and merges with normal-looking skin. The
surface of the lesions is moderately shiny and the central area looks
pale. There is minimal loss of sensation over the lesions. Nerve damage
is variable in BB leprosy. Many nerves may be thickened, and this effect
may be asymmetrical. BB leprosy is not commonly observed and rapidly changes its spectrum—rarely to BT leprosy but more often to BL
disease. The lepromin test is negative. Slit-skin smears of lesions show
a moderate number of AFB (2+ to 3+).
Borderline Lepromatous (BL) Leprosy In BL leprosy
(Fig. 179-5) there are numerous bilateral, round or oval, macular, diffusely infiltrated, erythematous or hypopigmented lesions with moderately defined borders. The lesions are usually 2–3 cm in diameter, may
have a coppery hue, and tend to become symmetrical. Some loss of
sensation may be detected, particularly over older lesions; however, no
loss of sensation is observed over fresh lesions. With disease progression, papules, nodules, and plaques develop over the macular lesions.
In untreated patients, new ill-defined skin lesions continue to develop.
Widespread but asymmetrical thickening of peripheral nerves, with or
without tenderness, leads to sensory and motor deficits. The lepromin
test gives negative results, as it does in all degrees of lepromatous leprosy. Slit-skin smear examination of lesions shows a bacteriologic index
varying from 3+ to 4+.
Lepromatous (LL) Leprosy LL leprosy (Fig. 179-6) presents
with innumerable bilateral, symmetrically distributed, diffusely
indurated, erythematous, copper-colored or skin-colored patches or
plaques. There is no loss of sensation over these lesions, which have
a smooth, shiny surface. The lesions spread over the face, earlobes,
ears, extensor aspects of the upper and lower extremities, back, and
buttocks. Induration can readily be recognized when lesions are viewed
tangentially under natural sunlight. The induration initially is of a
finer type but gradually becomes coarse, and lesions then progress to
papules, plaques, and nodules. Bilateral earlobe thickening and eyebrow loss occur. Coarse induration on the face sometimes results in
gross skin folds that lead to an appearance referred to as “lion face,”
particularly when associated with loss of eyebrows and thickening of
earlobes. Of all cases of LL leprosy, 10–15% are of the polar type (LLp)
from the time of lesion onset; the remaining cases downgrade from
the untreated borderline spectrum to subpolar LLs leprosy. Patients
with LLs disease develop nerve damage during the borderline stages.
In LLp disease, involvement of peripheral nerves occurs late and is
bilateral and symmetrical, with sensory loss in a “glove-and-stocking”
distribution. Slit-skin smear examination shows a bacteriologic index
of 4+ to 6+ with globi.
SYSTEMIC INVOLVEMENT In LL leprosy, AFB are found in the lymph
nodes, spleen, liver, bone marrow, adrenal glands, smooth and striated
muscles, tooth pulp, testes, oral cavity, nose, larynx, and eyes. Involvement of the testes leads first to sterility and then to gynecomastia and
impotence. Eye involvement includes corneal anesthesia; early on, this
manifestation is due to bacillary infiltration of corneal nerves, while
later it arises from damage to the ophthalmic division of the trigeminal
nerve. In addition, eye involvement includes episcleritis, iridocyclitis,
iris atrophy, cataract and glaucoma, lagophthalmos, corneal ulceration
and perforation, and blindness. The nose is the portal of entry for
M. leprae and is the earliest site of involvement in LL leprosy. Edema
and mucosal thickening occur in the inferior turbinate and nasal
septum, with crusting and epistaxis. Later, patients develop chronic
rhinitis with loss of smell sensation. Septal perforation due to bony
destruction, with typical saddle-nose disfigurement, is common in
advanced LL disease. In late-stage LL leprosy, ulceration of the tongue,
pharynx, hard and soft palates (leading to palate perforation), tonsillar
pillars, and uvula occurs. In the hands, slow resorption sets in, starting
from the distal end of the terminal phalanx and proceeding proximally
to involve the middle and proximal phalanges.
HISTOID LEPROSY Histoid leprosy is a rare form of LL leprosy in which
waxy, shiny, firm, symmetrical or asymmetrical nodules and plaques
are observed over normal-looking skin. Histologic examination of
these lesions shows specific spindle-cell granulomas. Slit-skin smear
examination reveals high bacteriologic and microbiologic indices without globi in most cases.
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