Leprosy

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Leprosy
Other namesHansen's disease (HD) [1]
Tropmed-91-216-g001.jpg
Rash on the chest and abdomen caused by leprosy
Pronunciation
Specialty Infectious diseases
Symptoms Decreased ability to feel pain [3]
Causes Mycobacterium leprae or Mycobacterium lepromatosis [4] [5]
Risk factors Close contact with a case of leprosy, living in poverty [3] [6]
TreatmentMultidrug therapy [4]
Medication Rifampicin, dapsone, clofazimine [3]
Frequency209,000 (2018) [4]
Named after Gerhard Armauer Hansen

Leprosy, also known as Hansen's disease (HD), is a long-term infection by the bacteria Mycobacterium leprae or Mycobacterium lepromatosis . [4] [7] Infection can lead to damage of the nerves, respiratory tract, skin, and eyes. [4] This nerve damage may result in a lack of ability to feel pain, which can lead to the loss of parts of a person's extremities from repeated injuries or infection through unnoticed wounds. [3] An infected person may also experience muscle weakness and poor eyesight. [3] Leprosy symptoms may begin within one year, but, for some people, symptoms may take 20 years or more to occur. [4]

Contents

Leprosy is spread between people, although extensive contact is necessary. [3] [8] Leprosy has a low pathogenicity and 95% of people who contract or who are exposed to M. leprae do not develop the disease. [9] Spread is thought to occur through a cough or contact with fluid from the nose of a person infected by leprosy. [8] [9] Genetic factors and immune function play a role in how easily a person catches the disease. [9] [10] Leprosy does not spread during pregnancy to the unborn child or through sexual contact. [8] Leprosy occurs more commonly among people living in poverty. [3] There are two main types of the disease – paucibacillary and multibacillary, which differ in the number of bacteria present. [3] A person with paucibacillary disease has five or fewer poorly pigmented, numb skin patches, while a person with multibacillary disease has more than five skin patches. [3] The diagnosis is confirmed by finding acid-fast bacilli in a biopsy of the skin. [3]

Leprosy is curable with multidrug therapy. [4] Treatment of paucibacillary leprosy is with the medications dapsone, rifampicin, and clofazimine for six months. [9] Treatment for multibacillary leprosy uses the same medications for 12 months. [9] A number of other antibiotics may also be used. [3] These treatments are provided free of charge by the World Health Organization. [4]

Leprosy is not highly contagious. [11] People with leprosy can live with their families and go to school and work. [12] In the 1980s, there were 5.2 million cases globally, but by 2020 this decreased to fewer than 200,000. [4] [13] [14] Most new cases occur in 14 countries, with India accounting for more than half. [3] [4] In the 20 years from 1994 to 2014, 16 million people worldwide were cured of leprosy. [4] About 200 cases per year are reported in the United States. [15] Central Florida accounted for 81% of cases in Florida and nearly 1 out of 5 leprosy cases nationwide. [16] Separating people affected by leprosy by placing them in leper colonies still occurs in some areas of India, [17] China, [18] Africa, [11] and Thailand. [19]

Leprosy has affected humanity for thousands of years. [3] The disease takes its name from the Greek word λέπρα (lépra), from λεπίς (lepís; 'scale'), while the term "Hansen's disease" is named after the Norwegian physician Gerhard Armauer Hansen. [3] Leprosy has historically been associated with social stigma, which continues to be a barrier to self-reporting and early treatment. [4] Leprosy is classified as a neglected tropical disease. [20] World Leprosy Day was started in 1954 to draw awareness to those affected by leprosy. [21] [4] The study of leprosy and its treatment is known as leprology. [22]

Signs and symptoms

Common symptoms present in the different types of leprosy include a runny nose; dry scalp; eye problems; skin lesions; muscle weakness; reddish skin; smooth, shiny, diffuse thickening of facial skin, ear, and hand; loss of sensation in fingers and toes; thickening of peripheral nerves; a flat nose from the destruction of nasal cartilages; and changes in phonation and other aspects of speech production. [23] In addition, atrophy of the testes and impotence may occur. [24]

Leprosy can affect people in different ways. [9] The average incubation period is five years. [4] People may begin to notice symptoms within the first year or up to 20 years after infection. [4] The first noticeable sign of leprosy is often the development of pale or pink coloured patches of skin that may be insensitive to temperature or pain. [25] Patches of discolored skin are sometimes accompanied or preceded by nerve problems including numbness or tenderness in the hands or feet. [25] [26] Secondary infections (additional bacterial or viral infections) can result in tissue loss, causing fingers and toes to become shortened and deformed, as cartilage is absorbed into the body. [27] [28] A person's immune response differs depending on the form of leprosy. [29]

Approximately 30% of people affected with leprosy experience nerve damage. [30] The nerve damage sustained is reversible when treated early, but becomes permanent when appropriate treatment is delayed by several months. Damage to nerves may cause loss of muscle function, leading to paralysis. It may also lead to sensation abnormalities or numbness, which may lead to additional infections, ulcerations, and joint deformities. [30]

Cause

M. leprae and M. lepromatosis

M. leprae, one of the causative agents of leprosy: As an acid-fast bacterium, M. leprae appears red when a Ziehl-Neelsen stain is used. Mycobacterium leprae in Magnification of 2000X.jpg
M. leprae, one of the causative agents of leprosy: As an acid-fast bacterium, M. leprae appears red when a Ziehl–Neelsen stain is used.

M. leprae and M. lepromatosis are the mycobacteria that cause leprosy. [30] M. lepromatosis is a relatively newly identified mycobacterium isolated from a fatal case of diffuse lepromatous leprosy in 2008. [5] [31] M. lepromatosis is indistinguishable clinically from M. leprae. [32]

M. leprae is an aerobic, rod-shaped, acid-fast bacterium with a waxy cell envelope characteristic of the genus Mycobacterium . [33]

M. leprae and M. lepromatosis are obligate intracellular pathogens, and cannot grow or be cultured outside of host tissues. [5] [34] However, they can be grown using research animals such as mice and armadillos. [35] [36]

Naturally occurring infections have been reported in nonhuman primates (including the African chimpanzee, the sooty mangabey, and the cynomolgus macaque), armadillos, [37] and red squirrels. [38] Multilocus sequence typing of the armadillo M. leprae strains suggests that they were of human origin for at most a few hundred years. [39] Thus, it is suspected that armadillos first acquired the organism incidentally from early European explorers of the Americas. [40] This incidental transmission was sustained in the armadillo population, and it may be transmitted back to humans, making leprosy a zoonotic disease (spread between humans and animals). [40]

Red squirrels (Sciurus vulgaris), a threatened species in Great Britain, were found to carry leprosy in November 2016. [41] It has been suggested that the trade in red squirrel fur, highly prized in the medieval period and intensively traded, may have been responsible for the leprosy epidemic in medieval Europe. [42] A pre-Norman era skull excavated in Hoxne, Suffolk, in 2017 was found to carry DNA from a strain of Mycobacterium leprae, which closely matched the strain carried by modern red squirrels on Brownsea Island, UK. [42] [43]

Risk factors

The greatest risk factor for developing leprosy is contact with another person infected by leprosy. [4] People who are exposed to a person who has leprosy are 5–8 times more likely to develop leprosy than members of the general population. [6] Leprosy also occurs more commonly among those living in poverty. [3] Not all people who are infected with M. leprae develop symptoms. [44] [45]

Conditions that reduce immune function, such as malnutrition, other illnesses, or genetic mutations, may increase the risk of developing leprosy. [6] Infection with HIV does not appear to increase the risk of developing leprosy. [46] Certain genetic factors in the person exposed have been associated with developing lepromatous or tuberculoid leprosy. [47]

Transmission

Transmission of leprosy occurs during close contact with those who are infected. [4] Transmission of leprosy is through the upper respiratory tract. [9] [48] Older research suggested the skin as the main route of transmission, but research has increasingly favored the respiratory route. [49] Transmission occurs through inhalation of bacilli present in upper airway secretion. [50]

Leprosy is not sexually transmitted and is not spread through pregnancy to the unborn child. [4] [8] The majority (95%) of people who are exposed to M. leprae do not develop leprosy; casual contact such as shaking hands and sitting next to someone with leprosy does not lead to transmission. [4] [51] People are considered non-infectious 72 hours after starting appropriate multi-drug therapy. [52]

Two exit routes of M. leprae from the human body that are often described are the skin and the nasal mucosa, although their relative importance is not clear. Lepromatous cases show large numbers of organisms deep in the dermis, but whether they reach the skin surface in sufficient numbers is doubtful. [53]

Leprosy may also be transmitted to humans by armadillos, although the mechanism is not fully understood. [8] [54] [55]

Genetics

Name Locus OMIM Gene
LPRS110p13 609888
LPRS26q25 607572 PARK2, PACRG
LPRS34q32 246300 TLR2
LPRS46p21.3 610988 LTA
LPRS54p14 613223 TLR1
LPRS613q14.11 613407

Not all people who are infected or exposed to M. leprae develop leprosy, and genetic factors are suspected to play a role in susceptibility to an infection. [56] Cases of leprosy often cluster in families and several genetic variants have been identified. [56] In many people who are exposed, the immune system can eliminate the leprosy bacteria during the early infection stage before severe symptoms develop. [57] A genetic defect in cell-mediated immunity may cause a person to be susceptible to develop leprosy symptoms after exposure to the bacteria. [58] The region of DNA responsible for this variability is also involved in Parkinson's disease, giving rise to current speculation that the two disorders may be linked at the biochemical level. [58]

Mechanism

Most leprosy complications are the result of nerve damage. The nerve damage occurs from direct invasion by the M. leprae bacteria and a person's immune response resulting in inflammation. [30] The molecular mechanism underlying how M. leprae produces the symptoms of leprosy is not clear, [14] but M. leprae has been shown to bind to Schwann cells, which may lead to nerve injury including demyelination and a loss of nerve function (specifically a loss of axonal conductance). [59] Numerous molecular mechanisms have been associated with this nerve damage including the presence of a laminin-binding protein and the glycoconjugate (PGL-1) on the surface of M. leprae that can bind to laminin on peripheral nerves. [59]

As part of the human immune response, white blood cell-derived macrophages may engulf M. leprae by phagocytosis. [59]

In the initial stages, small sensory and autonomic nerve fibers in the skin of a person with leprosy are damaged. [30] This damage usually results in hair loss to the area, a loss of the ability to sweat, and numbness (decreased ability to detect sensations such as temperature and touch). Further peripheral nerve damage may result in skin dryness, more numbness, and muscle weaknesses or paralysis in the area affected. [30] The skin can crack and if the skin injuries are not carefully cared for, there is a risk for a secondary infection that can lead to more severe damage. [30]

Diagnosis

Testing for loss of sensation with monofilament Monofilament testing.jpg
Testing for loss of sensation with monofilament

In countries where people are frequently infected, a person is considered to have leprosy if they have one of the following two signs:

Skin lesions can be single or many, and usually hypopigmented, although occasionally reddish or copper-colored. [4] The lesions may be flat (macules), raised (papules), or solid elevated areas (nodular). [4] Experiencing sensory loss at the skin lesion is a feature that can help determine if the lesion is caused by leprosy or by another disorder such as tinea versicolor. [4] [60] Thickened nerves are associated with leprosy and can be accompanied by loss of sensation or muscle weakness, but muscle weakness without the characteristic skin lesion and sensory loss is not considered a reliable sign of leprosy. [4]

In some cases, the presence of acid-fast leprosy bacilli in skin smears is considered diagnostic; however, the diagnosis is typically made without laboratory tests, based on symptoms. [4] If a person has a new leprosy diagnosis and already has a visible disability caused by leprosy, the diagnosis is considered late. [30]

In countries or areas where leprosy is uncommon, such as the United States, diagnosis of leprosy is often delayed because healthcare providers are unaware of leprosy and its symptoms. [61] Early diagnosis and treatment prevent nerve involvement, the hallmark of leprosy, and the disability it causes. [4] [61]

There is no recommended test to diagnose latent leprosy in people without symptoms. [9] Few people with latent leprosy test positive for anti PGL-1. [44] The presence of M. leprae bacterial DNA can be identified using a polymerase chain reaction (PCR)-based technique. [62] This molecular test alone is not sufficient to diagnose a person, but this approach may be used to identify someone who is at high risk of developing or transmitting leprosy such as those with few lesions or an atypical clinical presentation. [62] [63]

New approaches propose tools to diagnose leprosy through artificial intelligence. [64]

Classification

Several different approaches for classifying leprosy exist. There are similarities between the classification approaches.

WHORidley-Jopling ICD-10 MeSH Description Lepromin test
Paucibacillarytuberculoid ("TT"),
borderline
tuberculoid ("BT")
A30.1, A30.2TuberculoidIt is characterized by one or more hypopigmented skin macules and patches where skin sensations are lost because of damaged peripheral nerves that have been attacked by the human host's immune cells. TT is characterized by the formation of epithelioid cell granulomas with a large number of epithelioid cells. In this form of leprosy, Mycobacterium leprae are either absent from the lesion or occur in very small numbers. This type of leprosy is most benign. [59] [69] Positive
Multibacillarymidborderline
or
borderline ("BB")
A30.3BorderlineBorderline leprosy is of intermediate severity and is the most common form. Skin lesions resemble tuberculoid leprosy, but are more numerous and irregular; large patches may affect a whole limb, and peripheral nerve involvement with weakness and loss of sensation is common. This type is unstable and may become more like lepromatous leprosy or may undergo a reversal reaction, becoming more like the tuberculoid form.[ citation needed ]Negative
Multibacillaryborderline lepromatous ("BL"),
and lepromatous ("LL")
A30.4, A30.5LepromatousIt is associated with symmetric skin lesions, nodules, plaques, thickened dermis, and frequent involvement of the nasal mucosa resulting in nasal congestion and nose bleeds, but, typically, detectable nerve damage is late. Loss of eyebrows and lashes can be seen in advanced disease. [70] LL is characterized by the absence of epithelioid cells in the lesions. In this form of leprosy, Mycobacteria leprae are found in lesions in large numbers. This is the most unfavorable clinical variant of leprosy, which occurs with a generalized lesion of the skin, mucous membranes, eyes, peripheral nerves, lymph nodes, and internal organs. [59] [69] Histoid leprosy is a rare variation of multibacillary, lepromatous leprosy.Negative

Leprosy may also occur with only neural involvement, without skin lesions. [4] [71] [72] [73] [74] [75]

Complications

Leprosy may cause the victim to lose limbs and digits but not directly. M. leprae attacks nerve endings and destroys the body's ability to feel pain and injury. Without feeling pain, people with leprosy have an increased risk of injuring themselves. Injuries become infected and result in tissue loss. Fingers, toes, and limbs become shortened and deformed as the tissue is absorbed into the body. [76]

Prevention

Early detection of the disease is important, since physical and neurological damage may be irreversible even if cured. [4] Medications can decrease the risk of those living with people who have leprosy from acquiring the disease and likely those with whom people with leprosy come into contact outside the home. [14] The WHO recommends that preventive medicine be given to people who are in close contact with someone who has leprosy. [9] The suggested preventive treatment is a single dose of rifampicin (SDR) in adults and children over 2 years old who do not already have leprosy or tuberculosis. [9] Preventive treatment is associated with a 57% reduction in infections within 2 years and a 30% reduction in infections within 6 years. [9]

The Bacillus Calmette–Guérin (BCG) vaccine offers a variable amount of protection against leprosy in addition to its closely related target of tuberculosis. [77] It appears to be 26% to 41% effective (based on controlled trials) and about 60% effective based on observational studies with two doses possibly working better than one. [78] [79] The WHO concluded in 2018 that the BCG vaccine at birth reduces leprosy risk and is recommended in countries with high incidence of TB and people who have leprosy. [80] People living in the same home as a person with leprosy are suggested to take a BCG booster which may improve their immunity by 56%. [81] [82] Development of a more effective vaccine is ongoing. [14] [83] [84] [85]

A novel vaccine called LepVax entered clinical trials in 2017 with the first encouraging results reported on 24 participants published in 2020. [86] [87] If successful, this would be the first leprosy-specific vaccine available.

Treatment

MDT antileprosy drugs: standard regimens from 2010 MDTRegimens.jpg
MDT antileprosy drugs: standard regimens from 2010

A number of leprostatic agents are available for treatment. A three-drug regimen of rifampicin, dapsone and clofazimine is recommended for all people with leprosy, for six months for paucibacillary leprosy and 12 months for multibacillary leprosy. [9]

Multidrug therapy (MDT) remains highly effective, and people are no longer infectious after the first monthly dose. [4] MDT is safe and easy to use under field conditions because it is available in calendar-labelled blister packs. [4] Post-treatment relapse rates remain low. [4] Resistance has been reported in several countries, although the number of cases is small. [88] People with rifampicin-resistant leprosy may be treated with second-line medications such as fluoroquinolones, minocycline, or clarithromycin, but the treatment duration is 24 months because of their lower bactericidal activity. [89] Evidence on the potential benefits and harms of alternative regimens for drug-resistant leprosy is not available. [9]

For people with nerve damage, protective footwear may help prevent ulcers and secondary infection. [30] Canvas shoes may be better than PVC boots. [30] There may be no difference between double rocker shoes and below-knee plaster. [30] Topical ketanserin seems to have a better effect on ulcer healing than clioquinol cream or zinc paste, but the evidence for this is weak. [30] Phenytoin applied to the skin improves skin changes to a greater degree when compared to saline dressings. [30]

Outcomes

Although leprosy has been curable since the mid-20th century, left untreated it can cause permanent physical impairments and damage to a person's nerves, skin, eyes, and limbs. [4] Despite leprosy not being very infectious and having a low pathogenicity, there is still significant stigma and prejudice associated with the disease. [90] Because of this stigma, leprosy can affect a person's participation in social activities and may also affect the lives of their family and friends. [90] People with leprosy are also at a higher risk for problems with their mental well-being. [90] The social stigma may contribute to problems obtaining employment, financial difficulties, and social isolation. [90] Efforts to reduce discrimination and reduce the stigma surrounding leprosy may help improve outcomes for people with leprosy. [91]

Epidemiology

New cases of leprosy in 2016. Leprosy new case detection 2016 rates, 2016 (cropped).png
New cases of leprosy in 2016.
Disability-adjusted life year for leprosy per 100,000 inhabitants in 2004
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< 1.5
1.5-3
3-4.5
4.5-6
6-7.5
7.5-9
9-10.5
10.5-12
12-13.5
13.5-15
15-20
> 20 Leprosy world map - DALY - WHO2004.svg
Disability-adjusted life year for leprosy per 100,000 inhabitants in 2004
  No data
  < 1.5
  1.5–3
  3–4.5
  4.5–6
  6–7.5
  7.5–9
  9–10.5
  10.5–12
  12–13.5
  13.5–15
  15–20
  > 20

In 2018, there were 208,619 new cases of leprosy recorded, a slight decrease from 2017. [95] In 2015, 94% of the new leprosy cases were confined to 14 countries. [96] India reported the greatest number of new cases (60% of reported cases), followed by Brazil (13%) and Indonesia (8%). [96] Although the number of cases worldwide continues to fall, there are parts of the world where leprosy is more common, including Brazil, South Asia (India, Nepal, Bhutan), some parts of Africa (Tanzania, Madagascar, Mozambique), and the western Pacific. [96] About 150 to 250 cases are diagnosed in the United States each year. [97]

In the 1960s, there were tens of millions of leprosy cases recorded when the bacteria started to develop resistance to dapsone, the most common treatment option at the time. [4] [14] International (e.g., the WHO's "Global Strategy for Reducing Disease Burden Due to Leprosy") and national (e.g., the International Federation of Anti-Leprosy Associations) initiatives have reduced the total number and the number of new cases of the disease. [14] [98]

The number of new leprosy cases is difficult to measure and monitor because of leprosy's long incubation period, delays in diagnosis after onset of the disease, and lack of medical care in affected areas. [99] The registered prevalence of the disease is used to determine disease burden. [100] Registered prevalence is a useful proxy indicator of the disease burden, as it reflects the number of active leprosy cases diagnosed with the disease and receiving treatment with MDT at a given point in time. [100] The prevalence rate is defined as the number of cases registered for MDT treatment among the population in which the cases have occurred, again at a given point in time. [100]

Year2005200620072008200920102011201220132014201520162017201820192020202120222023
No. of new cases [101] 296,479258,980252,541249,018244,797228,488224,344232,847215,636213,861211,945217,927210,973208,613202,166127,506140,546174,059182,792

History

G. H. A. Hansen, discoverer of M. leprae Gerhard Armauer Hansen.jpg
G. H. A. Hansen, discoverer of M. leprae

Historical distribution

Using comparative genomics, in 2005, geneticists traced the origins and worldwide distribution of leprosy from East Africa or the Near East along human migration routes. They found four strains of M. leprae with specific regional locations: [102] Monot et al. (2005) determined that leprosy originated in East Africa or the Near East and traveled with humans along their migration routes, including those of trade in goods and slaves. The four strains of M. leprae are based in specific geographic regions where each predominantly occurs: [102]

This confirms the spread of the disease along the migration, colonisation, and slave trade routes taken from East Africa to India, West Africa to the New World, and from Africa to Europe and vice versa. [103]

Skeletal remains discovered in 2009 represent the oldest documented evidence for leprosy, dating to the 2nd millennium BC. [104] [105] Located at Balathal, Rajasthan, in northwest India, the discoverers suggest that, if the disease did migrate from Africa to India during the 3rd millennium BC "at a time when there was substantial interaction among the Indus Civilization, Mesopotamia, and Egypt, there needs to be additional skeletal and molecular evidence of leprosy in India and Africa to confirm the African origin of the disease". [106] A proven human case was verified by DNA taken from the shrouded remains of a man discovered by researchers from the Hebrew University of Jerusalem in a tomb in Akeldama, next to the Old City of Jerusalem, Israel, dated by radiocarbon methods to the first half of the 1st century. [107]

The oldest strains of leprosy known from Europe are from Great Chesterford in southeast England and date back to AD 415545. These findings suggest a different path for the spread of leprosy, meaning it may have originated in Western Eurasia. This study also indicates that there were more strains in Europe at the time than previously determined. [108]

Discovery and scientific progress

Literary attestation of leprosy is unclear because of the ambiguity of many early sources, including the Indian Atharvaveda and Kausika Sutra, the Egyptian Ebers Papyrus, and the Hebrew Bible's various sections regarding signs of impurity ( tzaraath ). [109] Leprotic symptoms are attested in the Indian doctor Sushruta's Compendium, originally dating to c. 600 BC but only surviving in emended texts no earlier than the 5th century. Symptoms consistent with leprosy were possibly described by Hippocrates in 460 BC. [110] However, Hansen's disease probably did not exist in Greece or the Middle East before the Common Era. [111] [112] [113] In 1846, Francis Adams produced The Seven Books of Paulus Aegineta which included a commentary on all medical and surgical knowledge and descriptions and remedies to do with leprosy from the Romans, Greeks, and Arabs. [114] [115]

Leprosy did not exist in the Americas before colonization by modern Europeans [116] nor did it exist in Polynesia until the middle of the 19th century. [117]

Distribution of leprosy around the world in 1891 Distribution of leprosy around the world Wellcome L0032805.jpg
Distribution of leprosy around the world in 1891

The causative agent of leprosy, M. leprae, was discovered by Gerhard Armauer Hansen in Norway in 1873, making it one of the first species of pathogenic bacteria identified. [118]

Treatment

Chaulmoogra tree oil was used topically to manage Hansen's disease for centuries. Chaulmoogra oil could not be taken orally without causing nausea or injected without forming an abscess. [119] In 1915, Alice Ball, the first Black woman to graduate from the University of Hawai'i with a masters in chemistry, discovered how to make the oil water-soluble. [119] This technique led to marked improvements in patients with Hansen's disease who were treated in Hawai'i. [119]

The first effective drug (promin) became available in the 1940s. [120] In the 1950s, dapsone was introduced. The search for further effective antileprosy drugs led to the use of clofazimine and rifampicin in the 1960s and 1970s. [121] Later, Indian scientist Shantaram Yawalkar and his colleagues formulated a combined therapy using rifampicin and dapsone, intended to mitigate bacterial resistance. [122] Multi-drug therapy (MDT) combining all three drugs was first recommended by the WHO in 1981. These three antileprosy drugs are still used in the standard MDT regimens. [123]

Leprosy was once believed to be highly contagious and was treated with mercury, as was syphilis, which was first described in 1530. Many early cases thought to be leprosy could actually have been syphilis. [124]

Resistance has developed to initial treatment. Until the introduction of MDT in the early 1980s, leprosy could not be diagnosed and treated successfully within the community. [125]

Japan still has sanatoriums (although Japan's sanatoriums no longer have active leprosy cases, nor are survivors held in them by law). [126]

The importance of the nasal mucosa in the transmission of M. leprae was recognized as early as 1898 by Schäffer, in particular, that of the ulcerated mucosa. [127] [ verification needed ] The mechanism of plantar ulceration in leprosy and its treatment was first described by Ernest W. Price. [128]

Etymology

The word "leprosy" comes from the Greek word "λέπος (lépos) – skin" and "λεπερός (leperós) – scaly man".[ citation needed ]

Society and culture

Two lepers denied entrance to town, 14th century Leprosorium.jpg
Two lepers denied entrance to town, 14th century

Treatment cost

Between 1995 and 1999, the WHO, with the aid of the Nippon Foundation, supplied all endemic countries with free multidrug therapy in blister packs, channeled through ministries of health. [4] This free provision was extended in 2000 and again in 2005, 2010, and 2015 with donations by the multidrug therapy manufacturer Novartis through the WHO. In the latest agreement signed between the company and the WHO in October 2015, the provision of free multidrug therapy by the WHO to all endemic countries will run until the end of 2025. [129] [4] At the national level, nongovernment organizations affiliated with the national program will continue to be provided with an appropriate free supply of multidrug therapy by the WHO. [130]

Historical texts

Written accounts of leprosy date back thousands of years. Various skin diseases translated as leprosy appear in the ancient Indian text, the Atharava Veda , by 600 BC. [131] Another Indian text, the Manusmriti (200 BC),  prohibited contact with those infected with the disease and made marriage to a person infected with leprosy punishable. [132]

The Hebraic root tsara or tsaraath (צָרַע, – tsaw-rah' – to be struck with leprosy, to be leprous) and the Greek (λεπρός–lepros), are of broader classification than the more narrow use of the term related to Hansen's Disease. [133] Any progressive skin disease (a whitening or splotchy bleaching of the skin, raised manifestations of scales, scabs, infections, rashes, etc....), as well as generalized molds and surface discoloration of any clothing, leather, or discoloration on walls or surfaces throughout homes all, came under the "law of leprosy" (Leviticus 14:54–57). [134] Ancient sources such as the Talmud (Sifra 63) make clear that tzaraath refers to various types of lesions or stains associated with ritual impurity and occurring on cloth, leather, or houses, as well as skin. Traditional Judaism and Jewish rabbinical authorities, both historical and modern, emphasize that the tsaraath of Leviticus is a spiritual ailment with no direct relationship to Hansen's disease or physical contagions. The relation of tsaraath to "leprosy" comes from translations of Hebrew Biblical texts into Greek and ensuing misconceptions. [135]

All three Synoptic Gospels of the New Testament describe instances of Jesus healing people with leprosy (Matthew 8:1–4, Mark 1:40–45, and Luke 5:12–16). The Bible's description of leprosy is congruous (if lacking detail) with the symptoms of modern leprosy, but the relationship between this disease, tzaraath, and Hansen's disease has been disputed. [136] The biblical perception that people with leprosy were unclean can be found in a passage from Leviticus 13: 44–46. While this text defines the leper as impure, it does not explicitly make a moral judgement on those with leprosy. [137] Some Early Christians believed that those affected by leprosy were being punished by God for sinful behavior. Moral associations have persisted throughout history. Pope Gregory the Great (540–604) and Isidore of Seville (560–636) considered people with the disease to be heretics. [138]

Middle Ages

Medieval leper bell Leprosy bell.JPG
Medieval leper bell

The social perception of leprosy in the general population was in general mixed. On one hand, people feared getting infected with the disease and thought of people suspected of leprosy to be unclean, untrustworthy, and occasionally morally corrupt. [138] On the other hand, Jesus' interaction with lepers, the writing of church leaders, and the Christian focus on charitable works led to viewing the lepers as "chosen by God" [139] or seeing the disease as a means of obtaining access to heaven. [140]

Early medieval understanding of leprosy was influenced by early Christian writers such as Gregory of Nazianzus and John Chrysostom, whose writings were later embraced by Byzantine and Latin writers. [141] Gregory, for example, did not only compose sermons urging Christians to assist victims of the disease, but also condemned pagans or Christians who justified rejecting lepers on the allegation that God had sent them the disease to punish them. As cases of leprosy increased during these years in the Eastern Roman Empire, becoming a major health issue, the ecclesiastic leaders of the time discussed how to assist those affected as well as change the attitude of society towards them. They also tried this by using the name "Holy disease" instead of the commonly used "Elephant's disease" (elephantiasis), implying that God did not create this disease to punish people but to purify them for heaven. [142] Although not always successful in persuading the public and a cure was never found by Greek medicians, they created an environment where victims could get palliative care and were never expressly banned from society, as sometimes happened in Western Europe. Theodore Balsamon, a 12th-century jurist in Constantinople, noted that lepers were allowed to enter the same churches, cities and assemblies that healthy people attended. [141]

As the disease became more prevalent in Western Europe in the fifth century, efforts began to set up permanent institutions to house and feed lepers. These efforts were, inclusively, the work of bishops in France at the end of the sixth century, such as in Chalon-sur-Saône. [141] The increase in hospitals or leprosaria (sing. leprosarium) that treated people with leprosy in the 12th and 13th century seems to indicate a rise in cases, [143] [144] [145] possibly in connection with the increase in urbanisation [146] as well as returning crusaders from the Middle East. [141] France alone had nearly 2,000 leprosaria during this period. [147] Additionally to the new leprosia, further steps were taken by secular and religious leaders to prevent further spread of the disease. The third Lateran Council of 1179 required lepers to have their own priests and churches [146] [ failed verification ] and a 1346 edict by King Edward expelled lepers from city limits. Segregation from mainstream society became common, and people with leprosy were often required to wear clothing that identified them as such or carry a bell announcing their presence. [147] As in the East, it was the Church who took care of the lepers due to the persisting moral stigma and who ran the leprosaria. [138] [148] Although the leprosaria in Western Europe removed the sick from society, they were never a place to quarantine them or from which they could not leave: lepers would go beg for alms for the upkeep of the leprosaria or meet with their families. [146] [141]

Multiple groups in Western Europe from the Middle Ages faced social ostracization and discrimination that was justified, in part, due to claims that they were the descendants of lepers. These groups included the Cagots and the Caquins. [149] [150] [151]

19th century

A 24-year-old man with leprosy (1886) Leprosy.jpg
A 24-year-old man with leprosy (1886)

Norway

Norway was the location of a progressive stance on leprosy tracking and treatment and played an influential role in European understanding of the disease. In 1832, Dr. JJ Hjort conducted the first leprosy survey, thus establishing a basis for epidemiological surveys. Subsequent surveys resulted in the establishment of a national leprosy registry to study the causes of leprosy and to track the rate of infection.[ citation needed ]

Early leprosy research throughout Europe was conducted by Norwegian scientists Daniel Cornelius Danielssen and Carl Wilhelm Boeck. Their work resulted in the establishment of the National Leprosy Research and Treatment Center. Danielssen and Boeck believed the cause of leprosy transmission was hereditary. This stance was influential in advocating for the isolation of those infected by sex to prevent reproduction. [152] [153] [154]

Leprosy and imperialism

Father Damien on his deathbed in 1889 Father Damien on his deathbed.jpg
Father Damien on his deathbed in 1889

Though leprosy rates were again on the decline in the Western world by the 1860s, authorities in the West frequently embraced isolation treatment due to a combination of reasons, including fears of the disease spreading from the Global South, efforts by Christian missionaries and a lack of understanding concerning bacteriology, medical diagnosis and how contagious the disease was. [155] The rapid expansion of Western imperialism during the Victorian era resulted in Westerners coming into increasing contact with regions where the disease was endemic, including British India. English surgeon Henry Vandyke Carter observed isolation treatment for leprosy patients first-hand while visiting Norway, applying these methods in British India with the financial and logistical assistance of Protestant missionaries. Colonialist and religious viewpoints of the disease continued to be a major factor in the treatment and public perception of the disease in the Global South until decolonization in the mid-twentieth century. [155]

20th century

India

In 1898, the colonial government in British India enacted the Leprosy Act of 1898, which mandated the compulsory segregation of people with leprosy by authorities in newly established leper asylums, where they were segregated by sex to prevent sexual activity. The act, which proved difficult to enforce, was repealed in 1983 by the Indian government after multidrug therapy had become widely available in India. In 1983, the National Leprosy Elimination Programme, previously the National Leprosy Control Programme, changed its methods from surveillance to the treatment of people with leprosy. India still accounts for over half of the global disease burden. According to WHO, new cases in India during 2019 diminished to 114,451 patients (57% of the world's total new cases). [156] [155] Until 2019, Indians could justify a petition for divorce with their spouse's diagnosis of leprosy. [157]

United States

The National Leprosarium at Carville, Louisiana, known in 1955 as the Louisiana Leper Home, was the only leprosy hospital in the mainland United States. Leprosy patients from all over the United States were sent to Carville to be kept in isolation away from the public, as not much about leprosy transmission was known at the time and stigma against those with leprosy was high (see Leprosy stigma). The Carville leprosarium was known for its innovations in reconstructive surgery for those with leprosy. In 1941, 22 patients at Carville underwent trials for a new drug called promin. The results were described as miraculous, and soon after the success of promin came dapsone, a medicine even more effective in the fight against leprosy. [158]

21st century

United States

Leprosy incidence peaked in the United States in 1983, followed by a steep decline. [159] However, case numbers have been slowly rising again since 2000. In 2020, 159 cases of leprosy were reported in the country. [159]

Stigma

Despite now effective treatment and education efforts, leprosy stigma continues to be problematic in developing countries where the disease is common. Leprosy is most common amongst impoverished populations where social stigma is likely to be compounded by poverty. Fears of ostracism, loss of employment, or expulsion from family and society may contribute to a delayed diagnosis and treatment. [160]

Folk beliefs, lack of education, and religious connotations of the disease continue to influence social perceptions of those affected in many parts of the world. In Brazil, for example, folklore holds that leprosy is a disease transmitted by dogs, or that it is associated with sexual promiscuity, or that it is a punishment for sins or moral transgressions (distinct from other diseases and misfortunes, which are in general thought of as being according to the will of God). [161] Socioeconomic factors also have a direct impact. Lower-class domestic workers who are often employed by those in a higher socioeconomic class may find their employment in jeopardy as physical manifestations of the disease become apparent. Skin discoloration and darker pigmentation resulting from the disease also have social repercussions. [162]

In extreme cases in northern India, leprosy is equated with an "untouchable" status that "often persists long after individuals with leprosy have been cured of the disease, creating lifelong prospects of divorce, eviction, loss of employment, and ostracism from family and social networks." [163]

Public policy

A goal of the World Health Organization is to "eliminate leprosy" and in 2016 the organization launched "Global Leprosy Strategy 2016–2020: Accelerating towards a leprosy-free world". [164] [165] Elimination of leprosy is defined as "reducing the proportion of leprosy patients in the community to very low levels, specifically to below one case per 10,000 population". [166] Diagnosis and treatment with multidrug therapy are effective, and a 45% decline in disease burden has occurred since multidrug therapy has become more widely available. [167] The organization emphasizes the importance of fully integrating leprosy treatment into public health services, effective diagnosis and treatment, and access to information. [167] The approach includes supporting an increase in health care professionals who understand the disease, and a coordinated and renewed political commitment that includes coordination between countries and improvements in the methodology for collecting and analysing data. [164]

Interventions in the "Global Leprosy Strategy 2016–2020: Accelerating towards a leprosy-free world": [164]

In some instances in India, community-based rehabilitation is embraced by local governments and NGOs alike. Often, the identity cultivated by a community environment is preferable to reintegration, and models of self-management and collective agency independent of NGOs and government support have been desirable and successful. [168]

Notable cases

Leprosy in media

Infection of animals

Wild nine-banded armadillos (Dasypus novemcinctus) in south central United States often carry Mycobacterium leprae. [186] This is believed to be because armadillos have a low body temperature. Leprosy lesions appear mainly in cooler body regions such as the skin and mucous membranes of the upper respiratory tract. Because of armadillos' armor, skin lesions are hard to see. [187] Abrasions around the eyes, nose and feet are the most common signs. Infected armadillos make up a large reservoir of M. leprae and may be a source of infection for some humans in the United States or other locations in the armadillos' home range. In armadillo leprosy, lesions do not persist at the site of entry in animals, M. leprae multiply in macrophages at the site of inoculation and lymph nodes. [188]

Across America, there has been a pattern of nine-banded armadillos (Dasypus novemcinctus) carrying Mycobacterium leprae. It was first demonstrated in 1971 to develop leprosy after inoculation with M. leprae. [189] As a result of their low body temperature their tissues commonly contain massive numbers of organisms which helps in the dissemination of the infection. Between 15-20% of Armadillos carry the M. leprae bacteria causing the risk of human infection when in contact with Armadillos quite high. [190]

Armadillos have been used in immunological research to fight leprosy. Some notable reagents include recombinant interleukin-2 and recombinant interferon-gamma reagents. [189] Additionally, they have been key and have been useful models of leprosy for studies regarding neuropathy. [191] In clinical procedures such as electrophysiological nerve conduction tests Armadillo's nerve function has been properly assessed. [191] Despite the studies mentioned regarding Armadillo's relationship to neuropathy and other effects of leprosy, there is still a lack of proper study on Armadillos, and in conducting more armadillo-specific regents our understanding of Leprosy’s effects on armadillos and possible humans can be found. Armadillos are a key component of modern-day research on leprosy.

There is a stigma surrounding armadillos and the carrying of leprosy. Because many people do not understand Armadillos very well it is common for people to think of them as being dangerous to society and, as a result valuing their lives less than other animals. But Armadillos are an essential part of our ecosystem, especially in areas where they are native. There is an issue on the other end of the spectrum as well. It has become more common in parts of America for people to eat raw or undercooked Armadillo meat as around 15-20% of American Armadillos carry leprosy [190] , making the chances high that if not properly handled with care, one will become infected. [192] We must find a happy medium to not put ourselves at risk of getting sick as a result of the Armadillos carrier status, but also not to harm Armadillos out of fear.

An outbreak in chimpanzees in West Africa is showing that the bacteria can infect another species and also possibly have additional rodent hosts. [193]

Studies have demonstrated that the disease is endemic in the UK red Eurasian squirrel population, with Mycobacterium leprae and Mycobacterium lepromatosis appearing in different populations. The Mycobacteria leprae strain discovered on Brownsea Island is equated to one thought to have died out in the human population in mediaeval times. [194] Despite this, and speculation regarding past transmission through trade in squirrel furs, there does not seem to be a high risk of squirrel to human transmission from the wild population. Although Leprosy continues to be diagnosed in immigrants to the UK, the last known human case of leprosy arising in the UK was recorded over 200 years ago. [195]

It has been shown that leprosy can reprogram cells in mouse [196] [197] and armadillo [198] [199] models, similar to how induced pluripotent stem cells are generated by the transcription factors Myc, Oct3/4, Sox2, and Klf4.

An animal that is a large component of the study on Leprosy is the mouse (Mus musculus) A notable study, conducted by Charles Shepard used mice to find how Leprosy, an infection that has a preference for cooler areas of the body, would work in a warm-blooded animal. This mice study helped further the understanding of how leprosy works in humans. This was called “The Mouse Model.” [189] The main findings were that even in mice whose immune systems were severely impaired and at a perceived high risk of developing leprosy, the body was still in most cases able to fight off leprosy. The findings suggest that in mice, the body will use their body's energy to fight leprosy. [189]

Using The Mouse Model Shepard was able to conduct new research regarding Leprosy. This model can now be used as a tool to further study M. leprae. [189] The Mouse Model takes a more easily accessible animal model to better understand this complex disease. Although Armadillos are one of the best animals to use to better understand M. leprae, they are not the only ones that can provide potential insights into this disease.

There are a few other up-and-coming models for M. leprae including the use of other animals including but not limited to mammals, birds, and cold-blooded animals. [189] These animals do not tend to give as great results as the Armadillos and the mice as different animals have different levels of disease resistance.

Related Research Articles

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<span class="mw-page-title-main">Leishmaniasis</span> Disease caused by parasites of the Leishmania type

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Leprosy stigma is a type of social stigma, a strong negative feeling towards a person with leprosy relating to their moral status in society. It is also referred to as leprosy-related stigma, leprostigma, and stigma of leprosy. Since ancient times, leprosy instilled the practice of fear and avoidance in many societies because of the associated physical disfigurement and lack of understanding behind its cause. Because of the historical trauma the word leprosy invokes, the disease is now referred to as Hansen's disease, named after Gerhard Armauer Hansen who discovered Mycobacterium leprae, the bacterial agent that causes Hansen's disease. Those who have suffered from Hansen's disease describe the impact of social stigma as far worse than the physical manifestations despite it being only mildly contagious and pharmacologically curable. This sentiment is echoed by Weis and Ramakrishna, who noted that "the impact of the meaning of the disease may be a greater source of suffering than symptoms of the disease".

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The history of leprosy was traced to its origins by an international team of 22 geneticists using comparative genomics of the worldwide distribution of Mycobacterium leprae. Monot et al. (2005) determined that leprosy originated in East Africa or the Near East and traveled with humans along their migration routes, including those of trade in goods and slaves. The four strains of M. leprae are based in specific geographic regions where each predominantly occurs:

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