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Sunday, March 31, 2019

Neglected tropical diseases

From Wikipedia, the free encyclopedia

Neglected tropical diseases
Ntd-world.jpg
Global overlap of six of the common NTDs. Specifically guinea worm disease, lymphatic filariasis, onchocerciasis, schistosomiasis, soil-transmitted helminths, and trachoma in 2011.
SpecialtyInfectious disease

Neglected tropical diseases (NTDs) are a diverse group of tropical infections which are common in low-income populations in developing regions of Africa, Asia, and the Americas. They are caused by a variety of pathogens such as viruses, bacteria, protozoa and helminths. These diseases are contrasted with the big three infectious diseases (HIV/AIDS, tuberculosis, and malaria), which generally receive greater treatment and research funding. In sub-Saharan Africa, the effect of these diseases as a group is comparable to malaria and tuberculosis. NTD co-infection can also make HIV/AIDS and tuberculosis more deadly.

In some cases, the treatments are relatively inexpensive. For example, the treatment for schistosomiasis is US$0.20 per child per year. Nevertheless, in 2010 it was estimated that control of neglected diseases would require funding of between US$2 billion and US$3 billion over the subsequent five to seven years. Some pharmaceutical companies have committed to donating all the drug therapies required, and mass drug administration (for example mass deworming) has been successfully accomplished in several countries. However, preventive measures are often more accessible in the developed world, but not universally available in poorer areas.

Within developed countries, neglected tropical diseases affect the very poorest in society. In the United States, there are up to 1.46 million families including 2.8 million children living on less than two dollars a day. In countries such as these, the burdens of neglected tropical diseases are often overshadowed by other public health issues. However, many of the same issues put populations at risk in developed as developing nations. For example, other problems can stem from poverty which expose individuals to the vectors of these disease, such as lack of adequate housing.

Twenty neglected tropical diseases are prioritized by the World Health Organization (WHO), though other organizations define NTDs differently. Chromoblastomycosis and other deep mycoses, scabies and other ectoparasites and snakebite envenoming were added to the list in 2017. These diseases are common in 149 countries, affecting more than 1.4 billion people (including more than 500 million children) and costing developing economies billions of dollars every year. They resulted in 142,000 deaths in 2013—down from 204,000 deaths in 1990. Of these 20, two were targeted for eradication (dracunculiasis (guinea-worm disease) by 2015 and yaws by 2020), and four for elimination (blinding trachoma, human African trypanosomiasis, leprosy and lymphatic filariasis by 2020).

List of diseases

There is some debate among the WHO, CDC, and infectious disease experts over which diseases are classified as neglected tropical diseases. Feasey, a researcher in neglected tropical diseases, notes 13 neglected tropical diseases: ascariasis, Buruli ulcer, Chagas disease, dracunculiasis, hookworm infection, human African trypanosomiasis, Leishmaniasis, leprosy, lymphatic filariasis, onchocerciasis, schistosomiasis, trachoma, and trichuriasis. Fenwick recognizes 12 "core" neglected tropical diseases: ascariasis, Buruli ulcer, Chagas disease, dracunculiasis, human African trypanosomiasis, Leishmaniasis, leprosy, lymphatic filariasis, onchocerciasis, schistosomiasis, trachoma, and trichuriasis.

These diseases result from four different classes of causative pathogens: (i) protozoa (for Chagas disease, human African trypanosomiasis, leishmaniases); (ii) bacteria (for Buruli ulcer, leprosy, trachoma, yaws), (iii) helminths or metazoan worms (for cysticercosis/taeniasis, dracunculiasis, echinococcosis, foodborne trematodiases, lymphatic filariasis, onchocerciasis, schistosomiasis, soil-transmitted helminthiasis); and (iv) viruses (dengue and chikungunya, rabies). 

The World Health Organization recognizes the twenty diseases below as neglected tropical diseases.

WHO/CDC PLOS
Major NTDs
Others
Buruli Ulcer
Chagas disease
Dengue & Chikungunya*
Dracunculiasis
Echinococcosis
Yaws
Fascioliasis
African trypanosomiasis
Leishmaniasis
Leprosy
Lymphatic filariasis
Onchocerciasis
Rabies
Schistosomiasis
Soil-transmitted helminthiasis
Cysticercosis
Trachoma
Scabies and other ectoparasites
Snakebite envenoming
Mycetoma and deep mycoses
Protozoan infections:
Helminth infections:
Viral infections:
Bacterial infections:
Fungal infections:
Ectoparasitic infections:
Podoconiosis
* Only WHO

Buruli ulcer

Buruli ulcer is caused by the bacterium Mycobacterium ulcerans. It is related to the family of organisms that cause tuberculosis and leprosy, but Mycobacterium ulcerans produces a toxin, mycolactone, that destroys tissue. The prevalence of Buruli ulcer is unknown. The risk of mortality is low, although secondary infections can be lethal. Morbidity takes the form of deformity, disability, and skin lesions, which can be prevented through early treatment and treated with antibiotics and surgery. It is found in Africa, Asia, and Latin America.

Chagas disease

A young boy from Panama with Chagas disease. It has manifested as an acute infection with swelling of one eye (chagoma).
 
Chagas disease is also known as American trypanosomiasis. There are approximately 15 million people infected with Chagas disease. The chance of morbidity is higher for immuno-compromised individuals, children, and elderly, but very low if treated early. Chagas disease does not kill victims rapidly, instead causing years of debilitating chronic symptoms. It is caused by a vector-borne protozoa and spread by contact with Trypanosoma cruzi infected feces of the triatomine (assassin) bug. The protozoan can enter the body via the bug's bite, skin breaks, or mucous membranes. Infection can result from eating infected food and coming into contact with contaminated bodily fluids. There are two phases of Chagas disease. The acute phase is usually asymptomatic. The first symptoms are usually skin chancres, unilateral purplish orbital oedema, local lymphoadenopathies, and fever accompanied by a variety of other symptoms depending on infection site. The chronic phase occurs in 30 percent of total infections and can take three forms, which are asymptomatic (most prevalent), cardiac, and digestive lesions.

Chagas disease can be prevented by avoiding insect bites through insecticide spraying, home improvement, bed nets, hygienic food, medical care, laboratory practices, and testing. It can also be treated with medication, although these may have severe side effects. It can be diagnosed through a serological test, although the test is not very accurate.

Dengue and chikungunya fever

There are 50–100 million dengue virus infections annually. Dengue fever is usually not fatal, but infection with one of four serotypes can increase later susceptibility to other serotypes, resulting in a potentially fatal disease called severe dengue. Dengue fever is caused by a flavivirus, and is spread mostly by the bite of the Aedes aegypti mosquito. No treatment for either dengue or severe dengue exists beyond palliative care. The symptoms are high fever and flu-like symptoms. It is found in Asia, Latin America, and Northern Australia.

Chikungunya is an arboviral disease transmitted by A. albopictus and A. aegypti mosquitoes. The virus was first isolated from an outbreak in Tanzania in 1952. Chikungunya virus is a member of the genus Alphavirus and family Togaviridae. The word chikungunya is from the Makonde which means "that which bends up," and this refers to the effect of the debilitating joint pain on the patient. The symptoms can be confused with dengue and include fever, rash, joint pain, and swelling. The disease mainly occurs in Africa and Asia.

Dracunculiasis

Dracunculiasis is also known as Guinea-worm disease. There were 126 cases of dracunculiasis in 2014, a decrease from 542 cases in 2012, and a substantial decrease from 3,500,000 cases in 1986. It is not fatal, but can cause months of inactivity. It is caused by drinking water contaminated by water fleas infected with guinea-worm larvae. Approximately one year after infection, a painful blister forms and one or more worms emerge. Worms can be up to one meter long.

It is usually treated by World Health Organization volunteers who clean and bandage wounds caused by worms and return daily to pull the worm out a few more inches. Dracunculiasis is preventable by water filtration, immediate case identification to prevent spread of disease, health education, and treating ponds with larvicide. An eradication program has been able to reduce prevalence. As of 2014, the four endemic countries are Chad, Ethiopia, Mali, and South Sudan.

Echinococcosis

The rates of echinococcosis is higher in rural areas, and there are more than one million people infected currently. Untreated alveolar echinococcosis is fatal. It is caused by ingesting parasites in animal feces. There are two versions of the disease: cystic and alveolar. Both versions involve an asymptomatic incubation period of several years. In the cystic version, liver cysts cause abdominal pain, nausea and vomiting while cysts in the lungs cause chronic cough, chest pain, and shortness of breath. In alveolar echinococcosis, a primary cyst develops, usually in the liver, in addition to weight loss, abdominal pain, general feeling of ill health, and signs of liver failure.

Surgery and drugs can both be used to treat echinococcosis. It can be prevented by deworming dogs, sanitation, proper disposal of animal feces, health education, and livestock vaccination. Cystic echinococcosis is found in the eastern portion of the Mediterranean region, northern Africa, southern and eastern Europe, the southern portion of South America, and central Asia. Alveolar echinococcosis is found in western and northern China, Russia, Europe, and northern North America. It can be diagnosed through imaging techniques and serological tests.

Endemic treponematoses (Yaws)

There are limited data available on the prevalence of yaws, although it primarily affects children. The mortality risk is very low, but the disease causes disfigurement and disability if untreated. The most common symptom is skin lesions. It is a chronic bacterial infection, transmitted by skin contact, and caused by treponemes. It is treated with antibiotics and can be prevented through improved hygiene and sanitation. Yaws is most prevalent in the warm, moist, tropical regions of the Americas, Africa, Asia, and the Pacific.

Foodborne trematodiases

The foodborne trematode infections include clonorchiasis, opisthorchiasis, fascioliasis, and paragonimiasis. These infections are all zoonotic, primarily affecting domestic or wild animals, but also transmitted to humans. They are acquired by eating food, such as raw fish, contaminated with the larval stages of the parasites. At least 40 million people are thought to be infected.

Human African trypanosomiasis

African trypanosomiasis is also known as African sleeping sickness. There are fewer than 10,000 cases currently. Human African trypanosomiasis is vector-borne, and spread through the bite of the tsetse fly. The most common symptoms are fever, headache, lymphadenopathy, nocturnal sleeping pattern, personality changes, cognitive decline, and coma. The disease is always fatal if untreated.

The current forms of treatment are highly toxic and ineffective as resistance is spreading. It is diagnosed through an inexpensive serological test.

Leishmaniasis

The three forms of leishmaniasis are visceral (Kala-azar), cutaneous, and mucocutaneous. There are an estimated 12 million people infected. It is fatal if untreated and 20,000 deaths from visceral leishmaniasis occur annually. It is a vector-borne disease that is caused by the bite of sandflies. At least 90 percent of visceral leishmaniasis occurs in Bangladesh, Brazil, Ethiopia, India, South Sudan, and Sudan. Cutaneous leishmaniasis occurs in Afghanistan, Algeria, Brazil, Colombia, Iran, Pakistan, Peru, Saudi Arabia, and Syria. Around 90 percent of mucocutaneous leishmaniasis occurs in Bolivia, Brazil, and Peru.

The only method of prevention is a vaccine that is under development and prevention of sandfly bites. Diagnosis can by made by identifying clinical signs, serological tests, or parasitological tests. Leishmaniasis can be treated with expensive medications.

Leprosy

There were 189,018 known cases of leprosy in March 2013, and 232,857 new cases were diagnosed in 2012. It is found in Angola, Brazil, Central African Republic, Democratic Republic of the Congo, India, Madagascar, Mozambique, Nepal, and Tanzania. There are one million to two million individuals currently disabled or disfigured due to past or present leprosy. It is caused by bacteria and transmitted through droplets from the mouth and nose of infected individuals. Leprosy causes disfigurement and physical disabilities if untreated. It is curable if treated early.

Treatment requires multidrug therapy. The BCG vaccine has some preventative effect against leprosy. Leprosy has a 5–20 year incubation period, and the symptoms are damage to the skin, nerves, eyes, and limbs.

Lymphatic filariasis

Lymphatic filariasis is also known as elephantiasis. There are approximately 120 million individuals infected and 40 million with deformities. Approximately two-thirds of cases are in Southwest Asia and one-third in Africa. Lymphatic filariasis is rarely fatal. Lymphatic filariasis has lifelong implications, such as lymphoedema of the limbs, genital disease, and painful recurrent attacks. Most people are asymptomatic, but have lymphatic damage. Up to 40 percent of infected individuals have kidney damage. It is a vector-borne disease, caused by nematode worms that are transmitted by mosquitoes.

It can be treated with cost-effective antihelminthic treatments, and washing skin can slow or even reverse damage. It is diagnosed with a finger-prick blood test.

Onchocerciasis

Onchocerciasis is also known as "river blindness". There are 37 million people infected and prevalence is higher in rural areas. Over 99 percent of cases are in Sub-Saharan Africa. It causes blindness, skin rashes, lesions, intense itching, and skin depigmentation. It is a vector-borne disease, caused by filarial worm infected blackflies.

It can be treated with ivermectin. It can be prevented by insecticide spraying or preventative dosing with ivermectin. The symptoms are generally itching and skin lesions.

Rabies

There are two forms of rabies: furious and paralytic. There are 60,000 deaths from rabies annually. It is mostly found in Asia and Africa. There is a higher prevalence in rural areas and it disproportionately affects children. Rabies is usually fatal after symptoms develop. It is caused by a lyssavirus transmitted through wounds or bites from infected animals. The first symptoms are fever and pain near the infection site which occur after a one to three month incubation period. Furious (more common type) rabies causes hyperactivity, hydrophobia, aerophobia, and death by cardio-respiratory arrest occurs within days. Paralytic rabies causes a slow progression from paralysis to coma to death.

It can be prevented in dogs by vaccination, and cleaning and disinfecting bite wounds (post-exposure prophylaxis). Rabies is undiagnosable before symptoms develop. It can be detected through tissue testing after symptoms develop.

Schistosomiasis

11-year-old boy with ascites and portal hypertension due to schistosomiasis (Agusan del Sur, Philippines)
 
There are over 200 million cases of schistosomiasis. Approximately 85 percent of cases are in sub-Saharan Africa. The disease can be fatal by causing bladder cancer and hematemesis. Schistosoma species have a complex life cycle that alternates between humans and freshwater snails. Infection occurs when skin comes into contact with contaminated freshwater in which the snail that carry the parasite are living. Symptoms for schistosomiasis are not caused by the worms but by the body’s reaction to the eggs. The eggs that do not pass out of the body can become lodged in the intestine or bladder, causing inflammation or scarring. Children who are repeatedly infected can develop anemia, malnutrition and learning difficulties. The symptoms are usually haematuria, bladder obstruction, renal failure, bladder cancer, periportal fibrosis, bladder fibrosis, liver fibrosis, portal hypertension, cervical lesions, ascites, and esophageal varices.

Inexpensive praziquantel can be used to treat individuals with schistosomiasis, but cannot prevent reinfection. The cost of prevention is US$0.32 per child per year. Mass deworming treatment with praziquantel, better access to safe water, sanitation, health education can all be used to prevent schistosomiasis. Vaccines are under development. It can be diagnosed through a serological test, but it often produces false negatives.

Soil-transmitted helminthiasis

Adult ascaris worms being removed from the bile duct of a patient in South Africa
 
The three major worm species responsible for soil-transmitted helminthiasis are Ascaris (roundworms), Trichuris (whipworm), the hookworms Necator americanus and Ancylostoma duodenale, and Strongyloides stercoralis. There are 1.5 billion currently infected. Soil-transmitted heminthiasis occurs in sub-Saharan Africa, the Americas, China, and east Asia. The mortality risk is very low. The most common symptoms are anemia, stunted growth, intestinal problems, lack of energy, and compromised physical and cognitive development. Infected children often fall behind in schooling. The severity of symptoms depends on the number of worms in the body.

Parasitic worms are generally transmitted via exposure to infected human feces and soil which are spread in the environment, for example, due to open defecation. The most common treatment is medicine. It can be prevented through hygienically prepared food and clean water, improved sanitation, periodic deworming, and health education. The World Health Organisation recommends mass deworming without prior diagnosis.

Taeniasis/cysticercosis

Cysticercosis is a tapeworm larvae infection, while taeniasis is infection with adult tapeworms . Both are found in Asia, Africa, Latin America, particularly on farms in which pigs are exposed to human excrement.

Cysticercosis is the most common preventable cause of epilepsy in the developing world. Cysticercosis occurs after ingestion of contaminated food, water, or soil. Cysts and lesions can cause headaches, blindness, seizures, hydrocephalus, meningitis, and dementia. Neurocystocercosis, or the parasitic infection of the nervous system, can be fatal. Taeniasis is not fatal. It is usually contracted after eating undercooked contaminated pork. Taeniasis has mild symptoms, including abdominal pain, nausea, diarrhea, or constipation.

Drugs are used to treat both diseases. Infection can be prevented through stricter meat-inspection standards, livestock confinement, improved hygiene and sanitation, health education, safe meat preparation, and identifying and treating human and pig carriers.

Trachoma

There are 21.4 million people infected with trachoma, of whom 2.2 million are partially blind and 1.2 million are blind. It is found in Africa, Asia, Central and South America, Middle East, and Australia. The disease disproportionately affects women and children. The mortality risk is very low, although multiple re-infections eventually lead to blindness. The symptoms are internally scarred eyelids, followed by eyelids turning inward. Trachoma is caused by a micro-organism that spreads through eye discharges (on hands, cloth, etc.) and by "eye-seeking flies".

It is treated with antibiotics. The only known prevention method is interpersonal hygiene.

Snakebite envenoming

Snakebite was added to the list in 2017, after years of criticism of the WHO by activists for not making it a priority. The greatest burden of snakebite morbidity is in India and Southeast Asia. Globally, there are an estimated 421,000 envenomings each year (about 1 in 4 snakebites) and 20,000 deaths, but snakebites often go unreported.

Health effect

Deworming treatment

Deworming treatments in infected children may have some nutritional benefit, as worms are often partially responsible for malnutrition. However, in areas where these infections are common, there is strong evidence that mass deworming campaigns do not have a positive effect on children's average nutritional status, levels of blood haemoglobin, cognitive abilities, performance at school or survival. To achieve health gains in the longer term, improvements in sanitation and hygiene behaviours are also required, together with deworming treatments.

Coinfection

Coinfection is a major concern with neglected tropical diseases, making NTDs more damaging than their mortality rates might portray. Because the factors that support neglected tropical diseases (poverty, inadequate healthcare, inadequate sanitation practices etc.) support all NTDs, they are often found in overlapping distributions. Helminth infections, as the most common infection of humans, are often found to be in multi-infection systems. For example, in Brazil, low socioeconomic status contributes to overcrowded housing. In these same areas, connection by Necator americanus and Schistosoma mansoni is common. The effect of each worm weakens the immune system of those infected, making infection from the other easier and more severe. For this reason, coinfection carries a higher risk of mortality. NTDs may also play a role in infection with other diseases, such as malaria, HIV/AIDS, and tuberculosis. The ability of helminths to manipulate the immune system may create a physiological environment that could exacerbate the progression of HIV/AIDS. Some evidence from Senegal, Malawi, and Thailand has shown that helminth infections raise the risk of malarial infection.

Integration of treatment

Inclusion of NTDs into initiatives for malaria, HIV/AIDS, and tuberculosis, as well as integration of NTD treatment programs, may have advantages given the strong link between these diseases and NTDs. Some neglected tropical diseases share common vectors (sandflies, black flies, and mosquitos). Both medicinal and vector control efforts may be combined.

A four-drug rapid-impact package has been proposed for widespread proliferation. Administration may be made more efficient by targeting multiple diseases at once, rather than separating treatment and adding work to community workers. This package is estimated to cost US$0.40 per patient. When compared to stand-alone treatment, the savings are estimated to be 26–47%. While more research must be done in order to understand how NTDs and other diseases interact in both the vector and the human stages, safety assessments have so far produced positive results.

Many neglected tropical diseases and other prevalent diseases share common vectors, creating another opportunity for treatment and control integration. One such example of this is malaria and lymphatic filariasis. Both diseases are transmitted by the same or related mosquito vectors. Vector control, through the distribution of insecticide treated nets, reduces the human contact with a wide variety of disease vectors. Integrated vector control may also alleviate pressure on mass drug administration, especially with respect to rapidly evolving drug resistance. Combining vector control and mass drug administration deemphasizes both, making each less susceptible to resistance evolution.

Economic effect

The low cost of treatment for NTDs can be attributed to the large scale of the programs, free provision of drugs by pharmaceutical companies, delivery modes of drugs, and the un-paid volunteers who distribute the drugs. The economic burden of NTDs is undervalued and therefore the corresponding economic effect and cost-effectiveness of decreased prevalence of NTDs is underestimated. The investment return on measures to control neglected tropical diseases is estimated to be between 14–30 percent, depending on the disease and region. The long-term benefits of deworming include a decrease in school absenteeism by 25 percent, and an increase in adult earnings by 20 percent.

The cost of treatment of some of these diseases, however, such as Buruli ulcer, can amount to over twice the yearly income of an average household in the lowest income quartile, while for the highest income quartile, the burden is slightly less than the average household income. These enormous financial costs often cause deferral of treatment and financial ruin, but there is inequality between the wealthy and poor in terms of economic burden. These diseases also cost the government in terms of health care and lost worker productivity through morbidity and shortened life spans. In Kenya, for example, deworming is estimated to increase average adult income by 40 percent, which is a benefit-to-cost ratio of 100. Each untreated case of Trachoma is estimated to cost US$118 in lost productivity. Each case of schistosomiasis causes a loss of 45.4 days of work per year. Most of the diseases cost the economies of various developing countries millions of dollars. Large scale prevention campaigns are predicted to increase agricultural output and education levels.

Social effect

Social stigma

Several NTDs, such as leprosy, cause severe deformities that result in social stigma. Stigma is considered to be the 'hidden burden' of neglected tropical diseases, and is not accounted for in measures such as DALYs. Other NTDs that carry heavy social stigma include onchocerciasis, lymphatic filariasis, plague, Buruli ulcer, leishmaniasis, and Chagas disease. Lymphatic filariasis, for example, causes severe deformities that can result in denial of marriage and inability to work. Studies in Ghana and Sri Lanka have demonstrated that support groups for patients with lymphatic filariasis can increase participants' self-esteem, quality of life, and social relations through social support and providing practical advice on how to manage their illness. The social effects of neglected tropical diseases have been shown to affect men and women in different ways. Men are socially stigmatized in a way that detrimentally affects their economic prospects. Women are more likely to be affected in the areas of marriage and family.

Effect on mental health

A 2012 review found that infection with a neglected tropical disease predisposes individuals to poor mental health. This is partially due to the social stigma that surround NTDs, but is also likely caused by the subsequent lack of access to health and social services. Overall, being a member of the infected community was found to cut individuals off from multiple aspects of society via civic rights, educational opportunities, and employment. The authors suggest that more research be directed into the psychological aspects of neglected tropical diseases in order to fully untangle their co-effects.

Gender

The effect of NTDs is tied to gender in some situations. NTDs disproportionately affect females. This is especially true in the cases of schistosomiasis, dengue, hookworm, and Chagas disease. There is also the added risk of hookworm infection during pregnancy and the potential to transfer diseases such as Chagas during pregnancy. A study in Uganda found that women were more easily able to obtain treatment because they had fewer occupational responsibilities than men and were more trusting of treatment, but ignorance of the effects of medicines on pregnant women prevented adequate care. The paper concludes that gender should be considered when designing treatment programs in Uganda. Additionally, women often bear a heavier social stigma in relation to the pressure to marry.

School attendance

The effects of mass deworming on school attendance is controversial. It has been argued that mass deworming has a positive effect on school attendance. A systematic review; however, found that there is little or no difference in attendance in children who receive mass deworming compared to children who did not. One study found that boys were enrolled in primary school for more years than boys who were in schools that did not offer such programs. Girls in the same study were about a quarter more likely to attend secondary school if they received treatment. Both groups went on to participate in more skilled sectors of the labor market. The economic growth generated from school programs such as this may balance out the actual expenses of the program. But the results of this study are disputed (i.a. due to a high risk of bias in the study) and the positive long-term outcomes of mass deworming remain unclear.

Reasons for neglect

This group of diseases has been overlooked because they mainly affect the poorest countries of the developing world and because of recent emphasis on decreasing the prevalence of HIV/AIDS, tuberculosis, and malaria. Far more resources are given to the "big three" diseases (HIV/AIDS, malaria, and tuberculosis) because of their higher mortality and public awareness rates. Neglected tropical diseases do not have a prominent cultural figure to champion the cause.

The importance of neglected tropical diseases has been underestimated since many are asymptomatic and have long incubation periods. The connection between a death and a neglected tropical disease that has been latent for a long period of time is not often realized. Areas of high endemicity are often in geographically isolated areas, making treatment and prevention much more difficult.

Stigma

Additionally, neglected tropical diseases are often associated with some kind of social stigma, making their treatment more complex. Public health research has only recently begun to focus on stigma as a component of the issue. From the 1960s onward, approximately one citation a year related to social stigma. In 2006, there were 458. Disease control is greatly affected by this stigma, as it decreases help-seeking and treatment adherence. Disease control programs, starting as early as the 1980s, have begun to integrate stigma mitigation into their offerings. In India, the leprosy program prioritized the message that "leprosy is curable, not hereditary" in order to inspire optimism in highly affected communities. The goal was to make leprosy a disease "like any other," so as to reduce stigma. Supplementally, the medical resources available in the area were optimized in order to fulfill the curable promise made.

Economic incentives

One reason for neglect for these diseases is that they are not commercial and consequently patents and profit play no role in stimulating innovation. Like all non-commercial areas, these diseases are the responsibility of governments and philanthropy (including industry philanthropy). Currently, the pharmaceutical industry views research and development as highly risky. For this reason, resources are not often put into the field of NTDs (as diseases of the poor) and new chemical products are often expensive. A review of public and private initiatives found that of the 1393 new chemical products that were marketed in the period of 1975 and 1999, just 16 related to tropical diseases and tuberculosis. The same review additionally found that there was a 13-fold greater chance of a drug entering the marking being for central-nervous-system disorders and cancer than an NTD.

Due to lack of incentive in the pharmaceutical industry, successful NTD treatment programs have often relied on the donation format. The Mectizan Donation Program has donated over 1.8 billion tablets of ivermectin. While often developed countries will rely on government-run and private partnerships to fund such projects, developing nations frequently have significantly lower per head per annum spending on these diseases.

Developed nations

Since 2008 the concept of neglected diseases of poverty has been developed and explored. This group overlaps with the neglected tropical diseases, which also pose a threat to human health in developed nations. In the United States alone, there are at least 12 million people suffering from these neglected parasitic infections. They make up a hidden disease burden among the poorest of wealthy societies. In developed nations, lack of knowledge in the healthcare industry and lack of conclusive diagnostic tests perpetuate the neglect of this group of diseases.

In the United States, high rates of parasitic infection can be found to be distributed along geographic, racial, and socio-economic lines. Within the African-American community, there may be up to 2.8 million cases of toxocariasis. Rates of toxocariasis, trichomoniasis, and other neglected infections occur in the United States at the same rate as in Nigeria. Within the Hispanic community, neglected infections are concentrated near the US–Mexico border. Vector-borne illnesses are especially high, with some rates approaching those of Latin America. Chagas disease was found in the US as early as the 1970s. However, in the developed world, diseases that are associated with poverty are often not addressed comprehensively. This may be due to lack of economic incentives and public policy failings. Here, a lack of awareness prevents effective policy generation and leaves health care services unequipped to address the issue. Additionally, there is little effort put into taking and maintaining large data sets on neglected disease in the United States and other developed nations. The first summit on the issue was held by the Adler Institute on Social Exclusion in the United States in 2009.

In Europe, a similar trend is seen. Neglected tropical diseases are concentrated in eastern and southern Europe, where poverty levels are the highest. The most prevalent diseases in this region are ascariasis, trichuriasis, zoonotic helminth infections, and visceral leishmaniasis. Migration paths to Europe, most notably to Spain, have brought diseases to Europe as well. As many as 6,000 cases of Chagas disease have been introduced via this method. In response to a growing awareness to the burden on these populations, the European Centre for Disease Prevention and Control has laid out ten public health guidelines. They cover a variety of topics, from health education and promotion to community partnerships and the development of a minority healthcare workforce.

Prevention

Prevention and eradication are important because "of the appalling stigma, disfigurement, blindness and disabilities caused by NTDs." The possibility of eliminating or eradicating dracunculiasis, leprosy, lymphatic filariasis, onchocerciasis, trachoma, sleeping sickness, visceral leishmaniasis, and canine rabies within the next ten years was the principal aim of the London Declaration on Neglected Tropical Diseases, which is a collaborative effort involving the WHO, the World Bank, the Bill & Melinda Gates Foundation, the world's 13 leading pharmaceutical companies, and government representatives from US, UK, United Arab Emirate, Bangladesh, Brazil, Mozambique and Tanzania. It was launched in January 2012.

While the current era has had a noticeable uptick in biological research into neglected tropical diseases, prevention may be supplemented by social and development outreach. Spiegal and his coauthors advocated for this to take the form of "social offset." Social offset entails the delegation of some of the funding for biotechnological research to social programs. The attempts to alleviate some of the surrounding factors (such as poverty, poor sanitation, overcrowding, poor healthcare etc.) that greatly exacerbate the conditions brought on by neglected tropical diseases. Projects such as these also strengthen the goal of sustained eliminations, rather than quickly addressing symptoms.

Policy initiatives

There are many prevention and eradication campaigns funded for example by the World Health Organization, US Agency for International Development, Bill and Melinda Gates Foundation, UK Department for International Development.

WHO Roadmap of 2012

WHO published in 2012 the NTD "roadmap" which contains milestones for 2015 and 2020 and which specifies targets for eradication, elimination, and intensified control of the different NTDs. For example:
  • NTDs planned to be eradicated: dracunculiasis (by the year 2015), endemic treponematoses (yaws) (by 2020);
  • NTDs planned to be eliminated globally by 2020: blinding trachoma, leprosy, human African trypanosomiasis, lymphatic filariasis;
  • NTDs planned to be eliminated in certain regions: rabies (by 2015 in Latin America, by 2020 in Southeast Asia and western Pacific regions), chagas disease (transmission through blood transfusion by 2015, intra-domiciliary transmission by 2020 in the region of the Americas), visceral leishmaniasis (by 2020 in the Indian subcontinent), oncocerciasis (by 2015 in Latin America), schistosomiasis (by 2015 in eastern Mediterranean region, Caribbean, Indonesia and the Mekong River basin, by 2020 in the region of the Americas and western Pacific region);
  • NTDs planned to be eliminated in certain countries: human African trypanosomiasis (by 2015 in 80 percent of areas in which it occurs), oncocerciasis (by 2015 in Yemen, by 2020 in selected countries in Africa), schistosomiasis (by 2020 in selected countries in Africa);
  • Intensified control with specific targets for the years 2015 and 2020 are provided for these NTDs: dengue, buruli ulcer, cutaneous leishmaniasis, taeniasis/cysticercosis and echinococcosis/hydatidosis, foodborne tremadode infections, soil-transmitted helmintheases.

Others

The U.S. Food and Drug Administration priority review voucher is an incentive for companies to invest in new drugs and vaccines for tropical diseases. A provision of the Food and Drug Administration Amendments Act (HR 3580) awards a transferable "priority review voucher" to any company that obtains approval for a treatment for one of the listed diseases. The voucher can later be used to accelerate review of an unrelated drug. This program is for all tropical diseases and includes medicines for malaria and tuberculosis. The first voucher given was for Coartem, a malaria treatment. It does not use or define the term "neglected" though most of the diseases listed are often included on lists of neglected diseases. 

The prize was proposed by Duke University faculty Henry Grabowski, Jeffrey Moe, and David Ridley in their 2006 Health Affairs paper: "Developing Drugs for Developing Countries." In 2007 United States Senators Sam Brownback (R-KS) and Sherrod Brown (D-OH) sponsored an amendment to the Food and Drug Administration Amendments Act of 2007. President George W. Bush signed the bill in September 2007.

Integration with WASH programs

Water, sanitation, and hygiene (WASH) interventions are essential in preventing many NTDs, for example soil-transmitted helminthiasis. Mass drug administrations alone will not protect people from re-infection. A more holistic and integrated approach to NTDs and WASH efforts will benefit both sectors along with the communities they are aiming to serve. This is especially true in areas that are endemic with more than one NTD.

In August 2015 the World Health Organization unveiled a global strategy and action plan to integrate WASH with other public health interventions in order to accelerate elimination of NTDs. The plan aims to intensify control or eliminate certain NTDs in specific regions by 2020 and refers to the NTD "roadmap" milestones from 2012 that include for example eradication of dracunculiasis by 2015 and of yaws by 2020, elimination of trachoma and lymphatic filariasis as public health problems by 2020, intensified control of dengue, schistosomiasis and soil-transmitted helminthiases.

A closer collaboration between WASH and NTD programmes can lead to synergies. They can be achieved through collaborative planning, delivery and evaluation of programmes, strengthening and sharing of evidence, and using monitoring tools to improve the equity of health services.

Reasons why WASH plays an important role in NTD prevention and patient care include:
  • NTDs affect more than one billion people in 149 countries. They occur mainly in regions with a lack of basic sanitation. About 2.4 billion people worldwide do not have adequate sanitation facilities. 663 million do not have access to improved drinking water sources.
  • One leading cause of preventable blindness is trachoma. The bacterial infection is transmitted through contact with eye-seeking flies, fingers, and fomites. Prevention components are facial cleanliness which requires water for face washing and environmental improvement which includes safe disposal of excreta to reduce fly populations.
  • Improved sanitation prevents soil-transmitted helminthiases. It impedes fecal pathogens such as intestinal worm eggs from contaminating the environment and infecting people through contaminated food, water, dirty hands, and direct skin contact with the soil.
  • Improved sanitation and water management can contribute to reduce proliferation of mosquitoes that transmit diseases, such as lymphatic filariasis, dengue and chikungunya. Breeding of the Culex mosquito which transmits filarial parasites is facilitated through poorly constructed latrines. Breeding of the Aedes aegypti and Aedes albopictus mosquitoes which transmit dengue and chikungunya can be prevented through safe storage of water.
  • Feces and urine which contain worm eggs can contaminate surface water and lead to transmission of schistosomiasis. This can be prevented through improved sanitation. Not only human but also animal (cow, buffalo) urine or feces can transmit some schistosome species. Therefore, it is important to protect freshwater from animals and animal waste.
  • Treatment of many NTDs require clean water and hygienic condition for healthcare facilities and households. For guinea worm, Buruli ulcer, or cutaneous leishmaniasis, wound management is needed to speed up healing and reduce disability. Lymphatic filariasis causes chronic disabilities. People who suffer from this disease need to maintain rigorous personal hygiene with water and soap to prevent secondary infections.
  • NTDs that lead to permanent disabilities make tasks such as carrying water long distances or accessing toilets difficult. However, people affected by these diseases often face stigma and can be excluded from accessing water and sanitation facilities. This increases their risk of poverty and severe illness. Clean water and soap are essential for these groups to maintain personal hygiene and dignity. Therefore, additional efforts to reduce stigma and exclusion are needed. In this manner, WASH can improve quality of life of people affected by NTDs.
  • In a meta-analysis safe water was associated with significantly reduced odds of Schistosoma infection, and adequate sanitation was associated with significantly lower odds of infection with both S. mansoni and S. haematobium.
  • A systematic review and meta-analysis showed that better hygiene in children is associated with lower odds of trachoma. Access to sanitation was associated with 15 percent lower odds of active trachoma and 33 percent lower odds of C. trachomatis infection of the eyes.
  • Another systematic review and meta-analysis found a correlation between WASH access and practices and lower odds of soil-transmitted helminthiasis infections by 33 to 77 percent. Persons who washed their hands after defecating were less than half as likely to be infected as those who did not. Traditionally, preventive chemotherapy is used as a measure of control, although this measure does not stop the transmission cycle and cannot prevent reinfection. In contrast, improved sanitation can.

Pharmaceutical market

Biotechnology companies in the developing world have targeted neglected tropical diseases due to need to improve global health.

Mass drug administration is considered a possible method for eradication, especially for lymphatic filariasis, onchocerciasis, and trachoma, although drug resistance is a potential problem. According to Fenwick, Pfizer donated 70 million doses of drugs in 2011 to eliminate trachoma through the International Trachoma Initiative. Merck has helped The African Programme for the Control of Onchocerciasis (APOC) and Oncho Elimination Programme for the Americas to greatly diminished the effect of Onchocerciasis by donating ivermectin. Merck KGaA pledged to give 200 million tablets of praziquantel over 10 years, the only cure for schistosomiasis. GlaxoSmithKline has donated two billion tablets of medicine for lymphatic filariasis and pledged 400 million deworming tablets per year for five years in 2010. Johnson & Johnson has pledged 200 million deworming tablets per year. Novartis has pledged leprosy treatment, EISAI pledged two billion tablets to help treat lymphatic filariasis.

NGO initiatives

There are currently only two donor-funded non-governmental organizations that focus exclusively on NTDs: the Schistosomiasis Control Initiative and Deworm the World. Despite under-funding, many neglected diseases are cost-effective to treat and prevent. The cost of treating a child for infection of soil transmitted helminths and schistosomes (some of the main causes of neglected diseases), is less than US$0.50 per year, when administered as part of school-based mass deworming by Deworm the World. This programme is recommended by Giving What We Can and the Copenhagen Consensus Centre as one of the most efficient and cost-effective solutions. The efforts of Schistosomiasis Control Initiative to combat neglected diseases include the use of rapid-impact packages: supplying schools with packages including four or five drugs, and training teachers in how to administer them.

Public-private initiatives

An alternative model to the profit-driven drug development emerged in the years 2000 to provide an answer to the needs of these neglected patients. Product development partnerships (PDPs) aim at implementing and accelerating the research and development (R&D) of safe and effective health tools (diagnostics, vaccines, drugs) to notably combat diseases that are neglected. Drugs for Neglected Diseases initiative (DNDi) is one of these PDPs that has already developed new treatments for NTDs.

The Sabin Vaccine Institute, founded in 1993, works to address the issues of vaccine-preventable diseases as well as NTDs. They run three main programs, Sabin Vaccine Development, Global Network for Neglected Tropical Diseases, and Vaccine Advocacy and Education. Their product development partnership affiliates them with the Texas Children's Hospital as well as the Baylor College of Medicine. Their major campaign, End7, aims to end seven of the most common NTDs (elephantiasis, river blindness, snail fever, trachoma, roundworm, whipworm and hookworm) by 2020. Through End7, college campuses undertake fundraising and educational initiatives for the broader goals of the campaign.

WIPO Re:Search was established in 2011 by the World Intellectual Property Organization in collaboration with BIO Ventures for Global Health (BVGH) and with the active participation of leading pharmaceutical companies and other private and public sector research organizations. It allows organizations to share their intellectual property, compounds, expertise, facilities and know-how royalty-free with qualified researchers worldwide working on new solutions for NTDs, malaria and tuberculosis.

In 2013, the Government of Japan, five Japanese pharmaceutical companies, the Bill and Melinda Gates Foundation, and the UNDP established a new public-private partnership, Global Health Innovative Technology Fund. They pledged over US$100 million to the fund over five years, to be awarded as grants to R&D partnerships across sectors in Japan and elsewhere, working to develop new drugs and vaccines for 17 neglected diseases, in addition to HIV, malaria and tuberculosis. Affordability of the resulting drugs and vaccines is one of the key criteria for grant awards.

Others

An open-access journal dedicated to neglected tropical diseases called PLoS Neglected Tropical Diseases first began publication in 2007. 

One of the first large-scale initiatives to address NTDs came from a collaboration between Kenneth Warren and the Rockefeller Foundation. Ken Warren is regarded as one of the founding figures in neglected tropical disease research. The Great Neglected Tropical Diseases Network was a consortium of scientists from all over the world, hand picked by Ken Warren, working to expand the research base in neglected diseases. Many of the scientists that he recruited had not been involved in NTD research before. The network ran from 1978 to 1988. Warren's vision was to establish units within biological labs across the world, dedicated to R&D. By forming a critical mass of scientists in NTD research, he hoped to attract new students into the field. The interdisciplinary group met annually to update the community on research progress. Much of the work done by this group focused on the understanding of the mechanisms behind infection. At these informally structured meetings, research partnerships were formed. Warren himself encouraged these partnerships, especially if they bridged the divide between developed and developing nations. Through the Great Neglected Tropical Disease Network, a great number of scientists were brought into the field of parasitology.

Epidemiology

The six most common NTDs include soil-transmitted helminths (STHs)—specifically roundworm (Ascaris lumbricoides), whipworm (Trichuris trichiura) and hookworms (Necator americanus and Ancylostoma duodenale)—schistosomiasis, trachoma, and lymphatic filariasis (LF). These diseases affect one-sixth of the world's population with 90 percent of the disease burden occurring in sub-Saharan Africa.

Information on the frequency of neglected tropical diseases is of low quality. It is currently difficult to summarize all of the information on this family of diseases. One effort to do so is the Global Burden of Disease framework. It aims to create a standardized method of measurement. The principle components of the approach involve 1) the measuring of premature mortality as well as disability, 2) the standardized usage of DALYs (disability-adjusted life years), and 3) wide spread inclusion of diseases and injury causes with the estimation of missing data. However, the DALY has been criticized as a 'systematic undervaluation' of disease burden. King asserts that the DALY emphasizes the individual too much, while ignoring the effects of the ecology of the disease. In order for the measure to become more valid, it may gave to take the context of poverty more into account. King also emphasizes that DALYs may not capture the non-linear effects of poverty on cost-utility analysis of disease control.

Tropical disease

From Wikipedia, the free encyclopedia

Tropical diseases are diseases that are prevalent in or unique to tropical and subtropical regions. The diseases are less prevalent in temperate climates, due in part to the occurrence of a cold season, which controls the insect population by forcing hibernation. However, many were present in northern Europe and northern America in the 17th and 18th centuries before modern understanding of disease causation. The initial impetus for tropical medicine was to protect the health of colonial settlers, notably in India under the British Raj. Insects such as mosquitoes and flies are by far the most common disease carrier, or vector. These insects may carry a parasite, bacterium or virus that is infectious to humans and animals. Most often disease is transmitted by an insect "bite", which causes transmission of the infectious agent through subcutaneous blood exchange. Vaccines are not available for most of the diseases listed here, and many do not have cures.

Human exploration of tropical rainforests, deforestation, rising immigration and increased international air travel and other tourism to tropical regions has led to an increased incidence of such diseases.

Health programmes

In 1975 the Special Programme for Research and Training in Tropical Diseases (TDR) was established to focus on neglected infectious diseases which disproportionately affect poor and marginalized populations in developing regions of Africa, Asia, Central America and South America. It was established at the World Health Organization, which is the executing agency, and is co-sponsored by the United Nations Children's Fund, United Nations Development Programme, the World Bank and the World Health Organization

TDR's vision is to foster an effective global research effort on infectious diseases of poverty in which disease endemic countries play a pivotal role. It has a dual mission of developing new tools and strategies against these diseases, and to develop the research and leadership capacity in the countries where the diseases occur. The TDR secretariat is based in Geneva, Switzerland, but the work is conducted throughout the world through many partners and funded grants. 

Some examples of work include helping to develop new treatments for diseases, such as ivermectin for onchocerciasis (river blindness); showing how packaging can improve use of artemesinin-combination treatment (ACT) for malaria; demonstrating the effectiveness of bednets to prevent mosquito bites and malaria; and documenting how community-based and community-led programmes increases distribution of multiple treatments.

The current TDR disease portfolio includes the following entries:
Although leprosy and tuberculosis are not exclusively tropical diseases, their high incidence in the tropics justifies their inclusion.

Other neglected tropical diseases

Additional neglected tropical diseases include:

Disease Causative Agent Comments
Hookworm Ancylostoma duodenale and Necator americanus
Trichuriasis Trichuris trichiura
Treponematoses Treponema pallidum pertenue, Treponema pallidum endemicum, Treponema pallidum carateum, Treponema pallidum pallidum
Buruli ulcer Mycobacterium ulcerans
Human African trypanosomiasis Trypanosoma brucei, Trypanosoma gambiense
Dracunculiasis Dracunculus medinensis
Leptospirosis Leptospira
Strongyloidiasis Strongyloides stercoralis
Foodborne trematodiases Trematoda
Neurocysticercosis Taenia solium
Scabies Sarcoptes scabiei
Flavivirus Infections Yellow fever virus, West Nile virus, dengue virus, Tick-borne encephalitis virus, Zika virus

Some tropical diseases are very rare, but may occur in sudden epidemics, such as the Ebola hemorrhagic fever, Lassa fever and the Marburg virus. There are hundreds of different tropical diseases which are less known or rarer, but that, nonetheless, have importance for public health.

Relation of climate to tropical diseases

The so-called "exotic" diseases in the tropics have long been noted both by travelers, explorers, etc., as well as by physicians. One obvious reason is that the hot climate present during all the year and the larger volume of rains directly affect the formation of breeding grounds, the larger number and variety of natural reservoirs and animal diseases that can be transmitted to humans (zoonosis), the largest number of possible insect vectors of diseases. It is possible also that higher temperatures may favor the replication of pathogenic agents both inside and outside biological organisms. Socio-economic factors may be also in operation, since most of the poorest nations of the world are in the tropics. Tropical countries like Brazil, which have improved their socio-economic situation and invested in hygiene, public health and the combat of transmissible diseases have achieved dramatic results in relation to the elimination or decrease of many endemic tropical diseases in their territory.

Climate change, global warming caused by the greenhouse effect, and the resulting increase in global temperatures, are possibly causing tropical diseases and vectors to spread to higher altitudes in mountainous regions, and to higher latitudes that were previously spared, such as the Southern United States, the Mediterranean area, etc. For example, in the Monteverde cloud forest of Costa Rica, global warming enabled Chytridiomycosis, a tropical disease, to flourish and thus force into decline amphibian populations of the Monteverde Harlequin frog. Here, global warming raised the heights of orographic cloud formation, and thus produced cloud cover that would facilitate optimum growth conditions for the implicated pathogen, B. dendrobatidis.

Prevention and treatment of tropical diseases

 
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Some of the strategies for controlling tropical diseases include:
  • Draining wetlands to reduce populations of insects and other vectors, or introducing natural predators of the vectors.
  • The application of insecticides and/or insect repellents) to strategic surfaces such as clothing, skin, buildings, insect habitats, and bed nets.
  • The use of a mosquito net over a bed (also known as a "bed net") to reduce nighttime transmission, since certain species of tropical mosquitoes feed mainly at night.
  • Use of water wells, and/or water filtration, water filters, or water treatment with water tablets to produce drinking water free of parasites.
  • Sanitation to prevent transmission through human waste.
  • In situations where vectors (such as mosquitoes) have become more numerous as a result of human activity, a careful investigation can provide clues: for example, open dumps can contain stagnant water that encourage disease vectors to breed. Eliminating these dumps can address the problem. An education campaign can yield significant benefits at low cost.
  • Development and use of vaccines to promote disease immunity.
  • Pharmacologic pre-exposure prophylaxis (to prevent disease before exposure to the environment and/or vector).
  • Pharmacologic post-exposure prophylaxis (to prevent disease after exposure to the environment and/or vector).
  • Pharmacologic treatment (to treat disease after infection or infestation).
  • Assisting with economic development in endemic regions. For example, by providing microloans to enable investments in more efficient and productive agriculture. This in turn can help subsistence farming to become more profitable, and these profits can be used by local populations for disease prevention and treatment, with the added benefit of reducing the poverty rate.

Entropy (information theory)

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