Wednesday, 15 April 2009

Tuberculosis

Tuberculosis (abbreviated as TB for tubercle bacillus or Tuberculosis) is a common and often deadly infectious disease caused by mycobacteria, in humans mainly Mycobacterium tuberculosis [1]. Tuberculosis usually attacks the lungs (as pulmonary TB) but can also affect the central nervous system, the lymphatic system, the circulatory system, the genitourinary system, the gastrointestinal system, bones, joints, and even the skin. Other mycobacteria such as Mycobacterium bovis, Mycobacterium africanum, Mycobacterium canetti, and Mycobacterium microti also cause tuberculosis, but these species are less common in humans.

The classic symptoms of tuberculosis are a chronic cough with blood-tinged sputum, fever, night sweats, and weight loss. Infection of other organs causes a wide range of symptoms. The diagnosis relies on radiology (commonly chest X-rays), a tuberculin skin test, blood tests, as well as microscopic examination and microbiological culture of bodily fluids. Tuberculosis treatment is difficult and requires long courses of multiple antibiotics. Contacts are also screened and treated if necessary. Antibiotic resistance is a growing problem in (extensively) multi-drug-resistant tuberculosis. Prevention relies on screening programs and vaccination, usually with Bacillus Calmette-Guérin (BCG vaccine).

Tuberculosis is spread through the air, when people who have the disease cough, sneeze, or spit. One third of the world's current population has been infected with M. tuberculosis, and new infections occur at a rate of one per second.[2] However, most of these cases will not develop the full-blown disease; asymptomatic, latent infection is most common. About one in ten of these latent infections will eventually progress to active disease, which, if left untreated, kills more than half of its victims. The proportion of people in the general population who become sick with tuberculosis each year is stable or falling worldwide but, because of population growth, the absolute number of new cases is still increasing.[3] In 2004, mortality and morbidity statistics included 14.6 million chronic active cases, 8.9 million new cases, and 1.6 million deaths, mostly in developing countries.[2] In addition, a rising number of people in the developed world are contracting tuberculosis because their immune systems are compromised by immunosuppressive drugs, substance abuse, or AIDS. The distribution of tuberculosis is not uniform across the globe with about 80% of the population in many Asian and African countries testing positive in tuberculin tests, while only 5-10% of the US population test positive.[1] It is estimated that the US has 25,000 new cases of tuberculosis each year, 40% of which occur in immigrants from countries where tuberculosis is endemic.[1]


Other names

In the past, tuberculosis has been called consumption, because it seemed to consume people from within, with a bloody cough, fever, pallor, and long relentless wasting. Other names included phthisis (Greek for consumption) and phthisis pulmonalis; scrofula (in adults), affecting the lymphatic system and resulting in swollen neck glands; tabes mesenterica, TB of the abdomen and lupus vulgaris, TB of the skin; wasting disease; white plague, because sufferers appear markedly pale; king's evil, because it was believed that a king's touch would heal scrofula; and Pott's disease, or gibbus of the spine and joints.[4][5] Miliary tuberculosis—now commonly known as disseminated TB—occurs when the infection invades the circulatory system resulting in lesions which have the appearance of millet seeds on X-ray.[4][6] TB is also called Koch's disease after the scientist Robert Koch.[7]

Symptoms

Main symptoms of pulmonary tuberculosis

When the disease becomes active, 75% of the cases are pulmonary TB. Symptoms include chest pain, coughing up blood, and a productive, prolonged cough for more than three weeks. Systemic symptoms include fever, chills, night sweats, appetite loss, weight loss, pallor, and often a tendency to fatigue very easily.[2]

Main sites of extrapulmonary tuberculosis

In the other 25% of active cases, the infection moves from the lungs, causing other kinds of TB, collectively denoted extrapulmonary tuberculosis[8]. This occurs more commonly in immunosuppressed persons and young children. Extrapulmonary infection sites include the pleura in tuberculosis pleurisy, the central nervous system in meningitis, the lymphatic system in scrofula of the neck, the genitourinary system in urogenital tuberculosis, and bones and joints in Pott's disease of the spine. An especially serious form is disseminated TB, more commonly known as miliary tuberculosis. Although extrapulmonary TB is not contagious, it may co-exist with pulmonary TB, which is contagious.[9]

Bacterial species

Scanning electron micrograph of Mycobacterium tuberculosis

The primary cause of TB, Mycobacterium tuberculosis, is an aerobic bacterium that divides every 16 to 20 hours, an extremely slow rate compared with other bacteria, which usually divide in less than an hour.[10] (For example, one of the fastest-growing bacteria is a strain of E. coli that can divide roughly every 20 minutes.) Since MTB has a cell wall but lacks a phospholipid outer membrane, it is classified as a Gram-positive bacterium. However, if a Gram stain is performed, MTB either stains very weakly Gram-positive or does not retain dye due to the high lipid & mycolic acid content of its cell wall.[11] MTB is a small rod-like bacillus that can withstand weak disinfectants and survive in a dry state for weeks. In nature, the bacterium can grow only within the cells of a host organism, but M. tuberculosis can be cultured in vitro.[12]

Using histological stains on expectorate samples from phlegm (also called sputum), scientists can identify MTB under a regular microscope. Since MTB retains certain stains after being treated with acidic solution, it is classified as an acid-fast bacillus (AFB).[1][11] The most common acid-fast staining technique, the Ziehl-Neelsen stain, dyes AFBs a bright red that stands out clearly against a blue background. Other ways to visualize AFBs include an auramine-rhodamine stain and fluorescent microscopy.

The M. tuberculosis complex includes three other TB-causing mycobacteria: M. bovis, M. africanum and M. microti. M. africanum is not widespread, but in parts of Africa it is a significant cause of tuberculosis.[13][14] M. bovis was once a common cause of tuberculosis, but the introduction of pasteurized milk has largely eliminated this as a public health problem in developed countries.[1][15] M. microti is mostly seen in immunodeficient people, although it is possible that the prevalence of this pathogen has been underestimated.[16]

Other known pathogenic mycobacteria include Mycobacterium leprae, Mycobacterium avium and M. kansasii. The last two are part of the nontuberculous mycobacteria (NTM) group. Nontuberculous mycobacteria cause neither TB nor leprosy, but they do cause pulmonary diseases resembling TB.[17]

Evolution

Tuberculosis has co-evolved with humans for many thousands of years, and perhaps as much as several million years,[18] but the oldest human remains showing signs of tuberculosis infection are 9,000 years old.[19] During this evolution, M. tuberculosis has lost numerous coding and non-coding regions in its genome, losses that can be used to distinguish between strains of the bacteria. The implication is that M. tuberculosis strains differ geographically, so their genetic differences can be used to track the origins and movement of each strain.[20]

Transmission

When people suffering from active pulmonary TB cough, sneeze, speak, or spit, they expel infectious aerosol droplets 0.5 to 5 µm in diameter. A single sneeze can release up to 40,000 droplets.[21] Each one of these droplets may transmit the disease, since the infectious dose of tuberculosis is very low and the inhalation of just a single bacterium can cause a new infection.[22]

People with prolonged, frequent, or intense contact are at particularly high risk of becoming infected, with an estimated 22% infection rate. A person with active but untreated tuberculosis can infect 10–15 other people per year.[2] Others at risk include people in areas where TB is common, people who inject drugs using unsanitary needles, residents and employees of high-risk congregate settings, medically under-served and low-income populations, high-risk racial or ethnic minority populations, children exposed to adults in high-risk categories, patients immunocompromised by conditions such as HIV/AIDS, people who take immunosuppressant drugs, and health care workers serving these high-risk clients.[23]

Transmission can only occur from people with active — not latent — TB [1]. The probability of transmission from one person to another depends upon the number of infectious droplets expelled by a carrier, the effectiveness of ventilation, the duration of exposure, and the virulence of the M. tuberculosis strain.[9] The chain of transmission can, therefore, be broken by isolating patients with active disease and starting effective anti-tuberculous therapy. After two weeks of such treatment, people with non-resistant active TB generally cease to be contagious. If someone does become infected, then it will take at least 21 days, or three to four weeks, before the newly infected person can transmit the disease to others.[24] TB can also be transmitted by eating meat infected with TB. Mycobacterium bovis causes TB in cattle. (See details below.)

Pathogenesis

Mycobacterium tuberculosis (stained red) in sputum

About 90% of those infected with Mycobacterium tuberculosis have asymptomatic, latent TB infection (sometimes called LTBI), with only a 10% lifetime chance that a latent infection will progress to TB disease.[1] However, if untreated, the death rate for these active TB cases is more than 50%.[25]

TB infection begins when the mycobacteria reach the pulmonary alveoli, where they invade and replicate within the endosomes of alveolar macrophages.[1][26] The primary site of infection in the lungs is called the Ghon focus, and is generally located in either the upper part of the lower lobe, or the lower part of the upper lobe[1]. Bacteria are picked up by dendritic cells, which do not allow replication, although these cells can transport the bacilli to local (mediastinal) lymph nodes. Further spread is through the bloodstream to other tissues and organs where secondary TB lesions can develop in other parts of the lung (particularly the apex of the upper lobes), peripheral lymph nodes, kidneys, brain, and bone.[1][27] All parts of the body can be affected by the disease, though it rarely affects the heart, skeletal muscles, pancreas and thyroid.[28]

Tuberculosis is classified as one of the granulomatous inflammatory conditions. Macrophages, T lymphocytes, B lymphocytes and fibroblasts are among the cells that aggregate to form a granuloma, with lymphocytes surrounding the infected macrophages. The granuloma functions not only to prevent dissemination of the mycobacteria, but also provides a local environment for communication of cells of the immune system. Within the granuloma, T lymphocytes (CD4+) secrete cytokines such as interferon gamma, which activates macrophages to destroy the bacteria with which they are infected.[29] T lymphocytes (CD8+) can also directly kill infected cells.[26]

Importantly, bacteria are not always eliminated within the granuloma, but can become dormant, resulting in a latent infection.[1] Another feature of the granulomas of human tuberculosis is the development of cell death, also called necrosis, in the center of tubercles. To the naked eye this has the texture of soft white cheese and was termed caseous necrosis.[30]

If TB bacteria gain entry to the bloodstream from an area of damaged tissue they spread through the body and set up many foci of infection, all appearing as tiny white tubercles in the tissues. This severe form of TB disease is most common in infants and the elderly and is called miliary tuberculosis. Patients with this disseminated TB have a fatality rate of approximately 20%, even with intensive treatment.[31]

In many patients the infection waxes and wanes. Tissue destruction and necrosis are balanced by healing and fibrosis.[30] Affected tissue is replaced by scarring and cavities filled with cheese-like white necrotic material. During active disease, some of these cavities are joined to the air passages bronchi and this material can be coughed up. It contains living bacteria and can therefore pass on infection. Treatment with appropriate antibiotics kills bacteria and allows healing to take place. Upon cure, affected areas are eventually replaced by scar tissue.[30]

Diagnosis

Tuberculosis is diagnosed definitively by identifying the causative organism (Mycobacterium tuberculosis) in a clinical sample (for example, sputum or pus). When this is not possible, a probable diagnosis may be made using imaging (X-rays or scans) and/or a tuberculin skin test.

The main problem with tuberculosis diagnosis is the difficulty in culturing this slow-growing organism in the laboratory (it may take 4 to 12 weeks for blood or sputum culture). A complete medical evaluation for TB must include a medical history, a physical examination, a chest X-ray, microbiological smears and cultures. It may also include a tuberculin skin test, a serological test. The interpretation of the tuberculin skin test depends upon the person's risk factors for infection and progression to TB disease, such as exposure to other cases of TB or immunosuppression.[9]

Currently, latent infection is diagnosed in a non-immunized person by a tuberculin skin test, which yields a delayed hypersensitivity type response to an extract made from M. tuberculosis.[1] Those immunized for TB or with past-cleared infection will respond with delayed hypersensitivity parallel to those currently in a state of infection, so the test must be used with caution, particularly with regard to persons from countries where TB immunization is common.[32] Tuberculin tests have the disadvantage in that they may produce false negatives, especially when the patient is co-morbid with sarcoidosis, Hodgkins lymphoma, malnutrition, or most notably active tuberculosis disease.[1] New TB tests are being developed that offer the hope of cheap, fast and more accurate TB testing. These include polymerase chain reaction detection of bacterial DNA, and assays to detect the release of interferon gamma in response to mycobacterial proteins such as ESAT-6.[33] These are not affected by immunization or environmental mycobacteria, so generate fewer false positive results.[34] The development of a rapid and inexpensive diagnostic test would be particularly valuable in the developing world.[35]

Progression

Progression from TB infection to TB disease occurs when the TB bacilli overcome the immune system defenses and begin to multiply. In primary TB disease—1–5% of cases—this occurs soon after infection.[1] However, in the majority of cases, a latent infection occurs that has no obvious symptoms[1]. These dormant bacilli can produce tuberculosis in 2–23% of these latent cases, often many years after infection.[36] The risk of reactivation increases with immunosuppression, such as that caused by infection with HIV. In patients co-infected with M. tuberculosis and HIV, the risk of reactivation increases to 10% per year.[1][25]

Patients with diabetes mellitus are at increased risk of contracting tuberculosis,[37] and they have a poorer response to treatment, possibly due to poorer drug absorption[38]

Other conditions that increase risk include IV drug abuse; recent TB infection or a history of inadequately treated TB; chest X-ray suggestive of previous TB, showing fibrotic lesions and nodules; silicosis; prolonged corticosteroid therapy and other immunosuppressive therapy; head and neck cancers; hematologic and reticuloendothelial diseases, such as leukemia and Hodgkin's disease; end-stage kidney disease; intestinal bypass or gastrectomy; chronic malabsorption syndromes; vitamin D deficiency;[39] and low body weight.[1][9]

Twin studies in the 1940s showed that susceptibility to TB was heritable. If one of a pair of twins got TB, then and the other was more likely to get TB if he was identical than if he was not.[40] Since then, specific gene polymorphisms in IL12B have been linked to tuberculosis susceptibility.[41]

Some drugs, including rheumatoid arthritis drugs that work by blocking tumor necrosis factor-alpha (an inflammation-causing cytokine), raise the risk of activating a latent infection due to the importance of this cytokine in the immune defense against TB.[42]

Treatment

Treatment for TB uses antibiotics to kill the bacteria. The two antibiotics most commonly used are rifampicin and isoniazid. However, instead of the short course of antibiotics typically used to cure other bacterial infections, TB requires much longer periods of treatment (around 6 to 12 months) to entirely eliminate mycobacteria from the body.[9] Latent TB treatment usually uses a single antibiotic, while active TB disease is best treated with combinations of several antibiotics, to reduce the risk of the bacteria developing antibiotic resistance.[43] People with latent infections are treated to prevent them from progressing to active TB disease later in life. However, treatment using Rifampicin and Pyrazinamide is not risk-free. The Centers for Disease Control and Prevention (CDC) notified healthcare professionals of revised recommendations against the use of rifampin plus pyrazinamide for treatment of latent tuberculosis infection, due to high rates of hospitalization and death from liver injury associated with the combined use of these drugs.[44]

Drug resistant tuberculosis is transmitted in the same way as regular TB. Primary resistance occurs in persons who are infected with a resistant strain of TB. A patient with fully-susceptible TB develops secondary resistance (acquired resistance) during TB therapy because of inadequate treatment, not taking the prescribed regimen appropriately, or using low quality medication.[43] Drug-resistant TB is a public health issue in many developing countries, as treatment is longer and requires more expensive drugs. Multi-drug-resistant tuberculosis (MDR-TB) is defined as resistance to the two most effective first-line TB drugs: rifampicin and isoniazid. Extensively drug-resistant TB (XDR-TB) is also resistant to three or more of the six classes of second-line drugs.[45] The DOTS (Directly Observed Treatment Short-course) strategy of tuberculosis treatment based on clinical trials done in the 1970s by Tuberculosis Research Centre, Chennai, India, focusing on a neglected area of infectious disease control is now showing promising results in effectively treating all TB cases in the community.

Prevention

TB prevention and control takes two parallel approaches. In the first, people with TB and their contacts are identified and then treated. Identification of infections often involves testing high-risk groups for TB. In the second approach, children are vaccinated to protect them from TB. Unfortunately, no vaccine is available that provides reliable protection for adults. However, in tropical areas where the levels of other species of mycobacteria are high, exposure to nontuberculous mycobacteria gives some protection against TB.[46]

The World Health Organization (W.H.O.) declared TB a global health emergency in 1993, and the Stop TB Partnership developed a Global Plan to Stop Tuberculosis that aims to save 14 million lives between 2006 and 2015.[47] Since humans are the only host of Mycobacterium tuberculosis, eradication would be possible: a goal that would be helped greatly by an effective vaccine.[48]

Vaccines

Many countries use Bacillus Calmette-Guérin (BCG) vaccine as part of their TB control programs, especially for infants. According to the W.H.O., this is the most often used vaccine worldwide, with 85% of infants in 172 countries immunized in 1993.[49] This was the first vaccine for TB and developed at the Pasteur Institute in France between 1905 and 1921.[50] However, mass vaccination with BCG did not start until after World War II.[51] The protective efficacy of BCG for preventing serious forms of TB (e.g. meningitis) in children is greater than 80%; its protective efficacy for preventing pulmonary TB in adolescents and adults is variable, ranging from 0 to 80%.[52]

In South Africa, the country with the highest prevalence of TB, BCG is given to all children under age three.[53] However, BCG is less effective in areas where mycobacteria are less prevalent; therefore BCG is not given to the entire population in these countries. In the USA, for example, BCG vaccine is not recommended except for people who meet specific criteria:[9]

  • Infants or children with negative skin test results who are continually exposed to untreated or ineffectively treated patients or will be continually exposed to multidrug-resistant TB.
  • Healthcare workers considered on an individual basis in settings in which a high percentage of MDR-TB patients has been found, transmission of MDR-TB is likely, and TB control precautions have been implemented and were not successful.

BCG provides some protection against severe forms of pediatric TB, but has been shown to be unreliable against adult pulmonary TB, which accounts for most of the disease burden worldwide. Currently, there are more cases of TB on the planet than at any other time in history and most agree there is an urgent need for a newer, more effective vaccine that would prevent all forms of TB—including drug resistant strains—in all age groups and among people with HIV.[54]

Several new vaccines to prevent TB infection are being developed. The first recombinant tuberculosis vaccine rBCG30, entered clinical trials in the United States in 2004, sponsored by the National Institute of Allergy and Infectious Diseases (NIAID).[55] A 2005 study showed that a DNA TB vaccine given with conventional chemotherapy can accelerate the disappearance of bacteria as well as protect against re-infection in mice; it may take four to five years to be available in humans.[56] A very promising TB vaccine, MVA85A, is currently in phase II trials in South Africa by a group led by Oxford University,[57] and is based on a genetically modified vaccinia virus. Many other strategies are also being used to develop novel vaccines,[58] including both subunit vaccines (fusion molecules composed of two recombinant proteins delivered in an adjuvant) such as Hybrid-1, HyVac4 or M72, and recombinant adenoviruses such as Ad35.[59][60][61][62] Some of these vaccines can be effectively administered without needles, making them preferable for areas where HIV is very common.[63] All of these vaccines have been successfully tested in humans and are now in extended testing in TB-endemic regions. In order to encourage further discovery, researchers and policymakers are promoting new economic models of vaccine development including prizes, tax incentives and advance market commitments.[64][65]

The Bill and Melinda Gates Foundation has been a strong supporter of new TB vaccine development. Most recently, they announced a $200 million grant to the Aeras Global TB Vaccine Foundation for clinical trials on up to six different TB vaccine candidates currently in the pipeline.[66]

Alcohol abuse

Alcohol abuse and use of illicit drugs are the most commonly (18.7%) reported behavioral risk factor among patients with TB in the United States.[67]

Epidemiology

Annual number of new reported TB cases. Data from WHO.[68]
300, orange = 200–300, yellow = 100–200, green = 50–100, blue =< grey =" n/a.">
World TB incidence. Cases per 100,000; Red => 300, orange = 200–300, yellow = 100–200, green = 50–100, blue =< grey =" n/a." href="http://en.wikipedia.org/wiki/WHO" title="WHO" class="mw-redirect">WHO, 2006.[69]

According to the World Health Organization (WHO), nearly 2 billion people—one third of the world's population—have been exposed to the tuberculosis pathogen.[70] Annually, 8 million people become ill with tuberculosis, and 2 million people die from the disease worldwide.[71] In 2004, around 14.6 million people had active TB disease with 9 million new cases. The annual incidence rate varies from 356 per 100,000 in Africa to 41 per 100,000 in the Americas.[2] Tuberculosis is the world's greatest infectious killer of women of reproductive age and the leading cause of death among people with HIV/AIDS.[72]

The rise in HIV infections and the neglect of TB control programs have enabled a resurgence of tuberculosis.[73] The emergence of drug-resistant strains has also contributed to this new epidemic with, from 2000 to 2004, 20% of TB cases being resistant to standard treatments and 2% resistant to second-line drugs.[45] The rate at which new TB cases occur varies widely, even in neighboring countries, apparently because of differences in health care systems.[74]

In 2005, the country with the highest estimated incidence of TB was Swaziland, with 1262 cases per 100,000 people. India has the largest number of infections, with over 1.8 million cases.[75] In developed countries, tuberculosis is less common and is mainly an urban disease. In the United Kingdom, TB incidences range from 40 per 100,000 in London to less than 5 per 100,000 in the rural South West of England;[76] the national average is 13 per 100,000. The highest rates in Western Europe are in Portugal (31.1 per 100,000 in 2005) and Spain (20 per 100,000). These rates compare with 113 per 100,000 in China and 64 per 100,000 in Brazil. In the United States, the overall tuberculosis case rate was 4.9 per 100,000 persons in 2004.[71] In Canada tuberculosis is still endemic in rural Manitoba.[77]

The incidence of TB varies with age. In Africa, TB primarily affects adolescents and young adults.[78] However, in countries where TB has gone from high to low incidence, such as the United States, TB is mainly a disease of older people, or of the immunocompromised [1][79].

There are a number of known factors that make people more susceptible to TB infection: worldwide the most important of these is HIV. Co-infection with HIV is a particular problem in Sub-Saharan Africa, due to the high incidence of HIV in these countries.[69][80] Smoking more than 20 cigarettes a day also increases the risk of TB by two to four times.[81][82] Diabetes mellitus is also an important risk factor that is growing in importance in developing countries.[83] Other disease states that increase the risk of developing tuberculosis are Hodgkin lymphoma, end-stage renal disease, chronic lung disease, malnutrition, and alcoholism. [1]

Diet may also modulate risk. For example, among immigrants in London from the Indian subcontinent, vegetarian Hindu Asians were found to have an 8.5 fold increased risk of tuberculosis, compared to Muslims who ate meat and fish daily.[84] Although a causal link is not proved by this data,[85] this increased risk could be caused by micronutrient deficiencies: possibly iron, vitamin B12 or vitamin D.[84] Further studies have provided more evidence of a link between vitamin D deficiency and an increased risk of contracting tuberculosis.[86][87] Globally, the severe malnutrition common in parts of the developing world causes a large increase in the risk of developing active tuberculosis, due to its damaging effects on the immune system.[88][89] Along with overcrowding, poor nutrition may contribute to the strong link observed between tuberculosis and poverty.[90][91]

History

Tubercular decay has been found in the spines of Egyptian mummies. Pictured: Egyptian mummy in the British Museum

Tuberculosis has been present in humans since antiquity. The earliest unambiguous detection of Mycobacterium tuberculosis is in the remains of bison dated 18,000 years before the present.[92] Whether tuberculosis originated in cattle and then transferred to humans, or diverged from a common ancestor infecting a different species, is currently unclear.[93] However, it is clear that M. tuberculosis is not directly descended from M. bovis, which seems to have evolved relatively recently.[94]

Skeletal remains show prehistoric humans (7000 BC) had TB [95], and tubercular decay has been found in the spines of mummies from 3000–2400 BC.[96] Phthisis is a Greek term for tuberculosis; around 460 BC, Hippocrates identified phthisis as the most widespread disease of the times involving coughing up blood and fever, which was almost always fatal.[97] Genetic studies suggest that TB was present in South America for about 2,000 years.[98] In South America, the earliest evidence of tuberculosis is associated with the Paracas-Caverna culture (circa 750 BC to circa 100 AD).[99]

Folklore

Before the Industrial Revolution, tuberculosis may sometimes have been regarded as vampirism. When one member of a family died from it, the other members that were infected would lose their health slowly. People believed that this was caused by the original victim draining the life from the other family members. Furthermore, people who had TB exhibited symptoms similar to what people considered to be vampire traits. People with TB often have symptoms such as red, swollen eyes (which also creates a sensitivity to bright light), pale skin, extremely low body heat, a weak heart and coughing blood, suggesting the idea that the only way for the afflicted to replenish this loss of blood was by sucking blood.[100] Another folk belief attributed it to being forced, nightly, to attend fairy revels, so that the victim wasted away owing to lack of rest; this belief was most common when a strong connection was seen between the fairies and the dead.[101] Similarly, but less commonly, it was attributed to the victims being "hagridden"—being transformed into horses by witches (hags) to travel to their nightly meetings, again resulting in a lack of rest.[101]

TB was romanticized in the nineteenth century. Many people believed TB produced feelings of euphoria referred to as "Spes phthisica" or "hope of the consumptive". It was believed that TB sufferers who were artists had bursts of creativity as the disease progressed. It was also believed that TB sufferers acquired a final burst of energy just before they died which made women more beautiful and men more creative.[102] In the early 20th century, some believed TB to be caused by masturbation.[103]

Study and treatment

The study of tuberculosis dates back to The Canon of Medicine written by Ibn Sina (Avicenna) in the 1020s. He was the first physician to identify pulmonary tuberculosis as a contagious disease, the first to recognise the association with diabetes, and the first to suggest that it could spread through contact with soil and water.[104][105] He developed the method of quarantine in order to limit the spread of tuberculosis.[106] In ancient times, treatments focused on sufferers' diets. Pliny the Elder described several methods in his Natural History: "wolf's liver taken in thin wine, the lard of a sow that has been fed upon grass, or the flesh of a she-ass taken in broth".[107]

Although it was established that the pulmonary form was associated with "tubercles" by Dr Richard Morton in 1689,[108][109] due to the variety of its symptoms, TB was not identified as a single disease until the 1820s and was not named "tuberculosis" until 1839 by J. L. Schönlein.[110] During the years 1838 – 1845, Dr. John Croghan, the owner of Mammoth Cave, brought a number of tuberculosis sufferers into the cave in the hope of curing the disease with the constant temperature and purity of the cave air; they died within a year.[111] The first TB sanatorium opened in 1859 in Görbersdorf, Germany (today Sokołowsko, Poland) by Hermann Brehmer.[112]

In regard to this claim, The Times for 15 January 1859, page 5, column 5, carries an advertisement seeking funds for the Bournemouth Sanatorium for Consumption, referring to the balance sheet for the past year, and offering an annual report to prospective donors, implying that this sanatorium was in existence at least in 1858.

Dr. Robert Koch discovered the tuberculosis bacilli.

The bacillus causing tuberculosis, Mycobacterium tuberculosis, was identified and described on 24 March 1882 by Robert Koch. He received the Nobel Prize in physiology or medicine in 1905 for this discovery.[113] Koch did not believe that bovine (cattle) and human tuberculosis were similar, which delayed the recognition of infected milk as a source of infection. Later, this source was eliminated by the pasteurization process. Koch announced a glycerine extract of the tubercle bacilli as a remedy for tuberculosis in 1890, calling it "tuberculin". It was not effective, but was later adapted as a test for pre-symptomatic tuberculosis.[114]

The first genuine success in immunizing against tuberculosis was developed from attenuated bovine-strain tuberculosis by Albert Calmette and Camille Guérin in 1906. It was called "BCG" (Bacillus of Calmette and Guérin). The BCG vaccine was first used on humans in 1921 in France,[50] but it was not until after World War II that BCG received widespread acceptance in the USA, Great Britain, and Germany.[51]

Tuberculosis, or "consumption" as it was commonly known, caused the most widespread public concern in the 19th and early 20th centuries as an endemic disease of the urban poor. In 1815, one in four deaths in England was of consumption; by 1918 one in six deaths in France were still caused by TB. In the 20th century, tuberculosis killed an estimated 100 million people.[115] After the establishment in the 1880s that the disease was contagious, TB was made a notifiable disease in Britain; there were campaigns to stop spitting in public places, and the infected poor were pressured to enter sanatoria that resembled prisons; the sanatoria for the middle and upper classes offered excellent care and constant medical attention.[112] Whatever the purported benefits of the fresh air and labor in the sanatoria, even under the best conditions, 50% of those who entered were dead within five years (1916).[112]

Public health campaigns tried to halt the spread of TB

The promotion of Christmas Seals began in Denmark during 1904 as a way to raise money for tuberculosis programs. It expanded to the United States and Canada in 1907 – 1908 to help the National Tuberculosis Association (later called the American Lung Association).

In the United States, concern about the spread of tuberculosis played a role in the movement to prohibit public spitting except into spittoons.

In Europe, deaths from TB fell from 500 out of 100,000 in 1850 to 50 out of 100,000 by 1950. Improvements in public health were reducing tuberculosis even before the arrival of antibiotics, although the disease remained a significant threat to public health, such that when the Medical Research Council was formed in Britain in 1913 its initial focus was tuberculosis research.[116]

It was not until 1946 with the development of the antibiotic streptomycin that effective treatment and cure became possible. Prior to the introduction of this drug, the only treatment besides sanatoria were surgical interventions, including the pneumothorax technique — collapsing an infected lung to "rest" it and allow lesions to heal — a technique that was of little benefit and was largely discontinued by the 1950s.[117] The emergence of multidrug-resistant TB has again introduced surgery as part of the treatment for these infections. Here, surgical removal of chest cavities will reduce the number of bacteria in the lungs, as well as increasing the exposure of the remaining bacteria to drugs in the bloodstream, and is therefore thought to increase the effectiveness of the chemotherapy.[118]

Hopes that the disease could be completely eliminated have been dashed since the rise of drug-resistant strains in the 1980s. For example, tuberculosis cases in Britain, numbering around 117,000 in 1913, had fallen to around 5,000 in 1987, but cases rose again, reaching 6,300 in 2000 and 7,600 cases in 2005.[119] Due to the elimination of public health facilities in New York and the emergence of HIV, there was a resurgence in the late 1980s.[120] The number of those failing to complete their course of drugs is high. New York had to cope with more than 20,000 TB patients with multidrug-resistant strains (resistant to, at least, both Rifampin and Isoniazid). The resurgence of tuberculosis resulted in the declaration of a global health emergency by the World Health Organization in 1993.[121]

Infection of other animals

Tuberculosis can be carried by mammals; domesticated species, such as cats and dogs, are generally free of tuberculosis, but wild animals may be carriers.

Mycobacterium bovis causes TB in cattle. An effort to eradicate bovine tuberculosis from the cattle and deer herds of New Zealand is underway. It has been found that herd infection is more likely in areas where infected vector species such as Australian brush-tailed possums come into contact with domestic livestock at farm/bush borders.[122] Controlling the vectors through possum eradication and monitoring the level of disease in livestock herds through regular surveillance are seen as a "two-pronged" approach to ridding New Zealand of the disease.

In the Republic of Ireland and the United Kingdom, badgers have been identified as one vector species for the transmission of bovine tuberculosis. As a result, governments have come under pressure from some quarters, primarily dairy farmers, to mount an active campaign of eradication of badgers in certain areas with the purpose of reducing the incidence of bovine TB. The effectiveness of culling on the incidence of TB in cattle is a contentious issue, with proponents and opponents citing their own studies to support their position.[123][124][125] For instance, a study by an Independent Study Group on badger culling reported on 18 June 2007 that it was unlikely to be effective and would only make a “modest difference” to the spread of TB and that "badger culling cannot meaningfully contribute to the future control of cattle TB"; in contrast, another report concluded that this policy would have a significant impact.[126] On July 4 2008, the UK government decided against a proposed random culling policy.[127]

References

Notes

  1. ^ a b c d e f g h i j k l m n o p q r s Kumar, Vinay; Abbas, Abul K.; Fausto, Nelson; & Mitchell, Richard N. (2007). Robbins Basic Pathology (8th ed.). Saunders Elsevier. pp. 516-522 ISBN 978-1-4160-2973-1
  2. ^ a b c d e World Health Organization (WHO). Tuberculosis Fact sheet N°104 - Global and regional incidence. March 2006, Retrieved on 6 October 2006.
  3. ^ "Scientific Facts on Drug-resistant Tuberculosis". GreenFacts Website. 2008-12-18. http://www.greenfacts.org/en/tuberculosis/l-2/1-mdr-tb-xdr.htm#0. Retrieved on 2009-03-25.
  4. ^ a b Tuberculosis Encyclopedia Britannica, 11th ed.
  5. ^ Rudy's List of Archaic Medical Terms English Glossary of Archaic Medical Terms, Diseases and Causes of Death. Accessed 9 October 2006
  6. ^ Disseminated tuberculosis NIH Medical Encyclopedia. Accessed 9 October 2006
  7. ^ Bhansali SK (April 1977). "Abdominal tuberculosis. Experiences with 300 cases". Am. J. Gastroenterol. 67 (4): 324–37. PMID 879148.
  8. ^ Extrapulmonary Tuberculosis: An Overview MARJORIE P. GOLDEN, M.D., Yale University School of Medicine and Hospital of Saint Raphael, New Haven, Connecticut. HOLENARASIPUR R. VIKRAM, M.D., Mayo Clinic, Scottsdale, Arizona.
  9. ^ a b c d e f Centers for Disease Control and Prevention (CDC), Division of Tuberculosis Elimination. Core Curriculum on Tuberculosis: What the Clinician Should Know. 4th edition (2000). Updated August 2003.
  10. ^ Cox R (2004). "Quantitative relationships for specific growth rates and macromolecular compositions of Mycobacterium tuberculosis, Streptomyces coelicolor A3(2) and Escherichia coli B/r: an integrative theoretical approach". Microbiology 150 (Pt 5): 1413–26. doi:10.1099/mic.0.26560-0. PMID 15133103. http://mic.sgmjournals.org/cgi/content/full/150/5/1413?view=long&pmid=15133103#R35.
  11. ^ a b Madison B (2001). "Application of stains in clinical microbiology". Biotech Histochem 76 (3): 119–25. doi:10.1080/714028138. PMID 11475314.
  12. ^ Parish T, Stoker N (1999). "Mycobacteria: bugs and bugbears (two steps forward and one step back)". Mol Biotechnol 13 (3): 191–200. doi:10.1385/MB:13:3:191. PMID 10934532.
  13. ^ Niemann S, Rüsch-Gerdes S, Joloba ML, et al (September 2002). "Mycobacterium africanum subtype II is associated with two distinct genotypes and is a major cause of human tuberculosis in Kampala, Uganda". J. Clin. Microbiol. 40 (9): 3398–405. doi:10.1128/JCM.40.9.3398-3405.2002. PMID 12202584. PMC: 130701. http://jcm.asm.org/cgi/pmidlookup?view=long&pmid=12202584.
  14. ^ Niobe-Eyangoh SN, Kuaban C, Sorlin P, et al (June 2003). "Genetic biodiversity of Mycobacterium tuberculosis complex strains from patients with pulmonary tuberculosis in Cameroon". J. Clin. Microbiol. 41 (6): 2547–53. doi:10.1128/JCM.41.6.2547-2553.2003. PMID 12791879. PMC: 156567. http://jcm.asm.org/cgi/pmidlookup?view=long&pmid=12791879.
  15. ^ Thoen C, Lobue P, de Kantor I (February 2006). "The importance of Mycobacterium bovis as a zoonosis". Vet. Microbiol. 112 (2-4): 339–45. doi:10.1016/j.vetmic.2005.11.047. PMID 16387455.
  16. ^ Niemann S, Richter E, Dalügge-Tamm H, Schlesinger H, Graupner D, Königstein B, Gurath G, Greinert U, Rüsch-Gerdes S (2000). "Two cases of Mycobacterium microti derived tuberculosis in HIV-negative immunocompetent patients". Emerg Infect Dis 6 (5): 539–42. PMID 10998387.
  17. ^ "Diagnosis and treatment of disease caused by nontuberculous mycobacteria. This official statement of the American Thoracic Society was approved by the Board of Directors, March 1997. Medical Section of the American Lung Association". Am J Respir Crit Care Med 156 (2 Pt 2): S1–25. 1997. PMID 9279284.
  18. ^ Gutierrez MC, Brisse S, Brosch R, et al (September 2005). "Ancient origin and gene mosaicism of the progenitor of Mycobacterium tuberculosis". PLoS Pathog. 1 (1): e5. doi:10.1371/journal.ppat.0010005. PMID 16201017. PMC: 1238740. http://www.plospathogens.org/article/info:doi/10.1371/journal.ppat.0010005.
  19. ^ Hershkovitz I, Donoghue HD, Minnikin DE, et al. (2008). "Detection and molecular characterization of 9000-year-old Mycobacterium tuberculosis from a neolithic settlement in the eastern mediterranean". PLoS ONE 3 (10): e3426. doi:10.1371/journal.pone.0003426.
  20. ^ Rao K, Kauser F, Srinivas S, Zanetti S, Sechi L, Ahmed N, Hasnain S (2005). "Analysis of genomic downsizing on the basis of region-of-difference polymorphism profiling of Mycobacterium tuberculosis patient isolates reveals geographic partitioning". J Clin Microbiol 43 (12): 5978–82. doi:10.1128/JCM.43.12.5978-5982.2005. PMID 16333085.
  21. ^ Cole E, Cook C (1998). "Characterization of infectious aerosols in health care facilities: an aid to effective engineering controls and preventive strategies". Am J Infect Control 26 (4): 453–64. doi:10.1016/S0196-6553(98)70046-X. PMID 9721404.
  22. ^ Nicas M, Nazaroff WW, Hubbard A (2005). "Toward understanding the risk of secondary airborne infection: emission of respirable pathogens". J Occup Environ Hyg 2 (3): 143–54. doi:10.1080/15459620590918466. PMID 15764538.
  23. ^ Griffith D, Kerr C (1996). "Tuberculosis: disease of the past, disease of the present". J Perianesth Nurs 11 (4): 240–5. doi:10.1016/S1089-9472(96)80023-2. PMID 8964016.
  24. ^ "Causes of Tuberculosis". Mayo Clinic. 2006-12-21. http://www.mayoclinic.com/health/tuberculosis/DS00372/DSECTION=3. Retrieved on 2007-10-19.
  25. ^ a b Onyebujoh, Phillip and Rook, Graham A. W. World Health Organization Disease Watch: Focus: Tuberculosis. December 2004. Accessed 7 October 2006.
  26. ^ a b Houben E, Nguyen L, Pieters J (2006). "Interaction of pathogenic mycobacteria with the host immune system". Curr Opin Microbiol 9 (1): 76–85. doi:10.1016/j.mib.2005.12.014. PMID 16406837.
  27. ^ Herrmann J, Lagrange P (2005). "Dendritic cells and Mycobacterium tuberculosis: which is the Trojan horse?". Pathol Biol (Paris) 53 (1): 35–40. PMID 15620608.
  28. ^ Agarwal R, Malhotra P, Awasthi A, Kakkar N, Gupta D (2005). "Tuberculous dilated cardiomyopathy: an under-recognized entity?". BMC Infect Dis 5 (1): 29. doi:10.1186/1471-2334-5-29. PMID 15857515. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=15857515.
  29. ^ Kaufmann S (2002). "Protection against tuberculosis: cytokines, T cells, and macrophages". Ann Rheum Dis 61 Suppl 2: ii54–8. PMID 12379623.
  30. ^ a b c Grosset J (2003). "Mycobacterium tuberculosis in the extracellular compartment: an underestimated adversary". Antimicrob Agents Chemother 47 (3): 833–6. doi:10.1128/AAC.47.3.833-836.2003. PMID 12604509.
  31. ^ Kim J, Park Y, Kim Y, Kang S, Shin J, Park I, Choi B (2003). "Miliary tuberculosis and acute respiratory distress syndrome". Int J Tuberc Lung Dis 7 (4): 359–64. PMID 12733492.
  32. ^ Rothel J, Andersen P (2005). "Diagnosis of latent Mycobacterium tuberculosis infection: is the demise of the Mantoux test imminent?". Expert Rev Anti Infect Ther 3 (6): 981–93. doi:10.1586/14787210.3.6.981. PMID 16307510.
  33. ^ Nahid P, Pai M, Hopewell P (2006). "Advances in the diagnosis and treatment of tuberculosis". Proc Am Thorac Soc 3 (1): 103–10. doi:10.1513/pats.200511-119JH. PMID 16493157.
  34. ^ Pai M, Zwerling A, Menzies D (June 2008). "Systematic Review: T-Cell-Based Assays for the Diagnosis of Latent Tuberculosis Infection: An Update". Ann. Intern. Med. 149 (3): 1–9. PMID 18593687.
  35. ^ Reddy JR, Kwang J, Lechtenberg KF, Khan NC, Prasad RB, Chengappa MM (January 2002). "An immunochromatographic serological assay for the diagnosis of Mycobacterium tuberculosis". Comp. Immunol. Microbiol. Infect. Dis. 25 (1): 21–7. doi:10.1016/S0147-9571(01)00016-9. PMID 11831744.
  36. ^ Parrish N, Dick J, Bishai W (1998). "Mechanisms of latency in Mycobacterium tuberculosis". Trends Microbiol 6 (3): 107–12. doi:10.1016/S0966-842X(98)01216-5. PMID 9582936.
  37. ^ Restrepo BI (2007). "Convergence of the tuberculosis and diabetes epidemics: Renewal of old acquaintances". Clin Infect Dis 45: 436–438. doi:10.1086/519939.
  38. ^ Nijland HMJ, Ruslami R, Stalenhoef JE, et al. (2006). "Exposure to rifampicin is strongly reduced in patients with tuberculosis and type 2 diabetes". Clin Infect Dis 43 (7): 848–854. doi:10.1086/507543. PMID 16941365.
  39. ^ Nnoaham KE, Clarke A (2008). "Low serum vitamin D levels and tuberculosis: a systematic review and meta-analysis". Int J Epidemiol 37: 113–19. doi:10.1093/ije/dym247. PMID 18245055.
  40. ^ Kallmann FJ, Reisner D (1942). "Twin studies on the significance of genetic factors in tuberculosis". Am Rev Tuberc 16: 593–617.
  41. ^ Tso HW, Lau YL, Tam CM, Wong HS, Chiang KS (2004). "Associations between IL12B polymorphisms and tuberculosis in the Hong Kong Chinese population". J Infect Dis 190 (5): 913–9. doi:10.1086/422693. PMID 15295696.
  42. ^ Mutlu G, Mutlu E, Bellmeyer A, Rubinstein I (2006). "Pulmonary adverse events of anti-tumor necrosis factor-alpha antibody therapy". Am J Med 119 (8): 639–46. doi:10.1016/j.amjmed.2006.01.015. PMID 16887405.
  43. ^ a b O'Brien R (1994). "Drug-resistant tuberculosis: etiology, management and prevention". Semin Respir Infect 9 (2): 104–12. PMID 7973169.
  44. ^ "Update: adverse event data and revised American Thoracic Society/CDC recommendations against the use of rifampin and pyrazinamide for treatment of latent tuberculosis infection—United States, 2003". MMWR Morb Mortal Wkly Rep 52 (31): 735–9. 2003. PMID 12904741. http://www.cdc.gov/mmwr/preview/mmwrhtml/mm5231a4.htm.
  45. ^ a b "Emergence of Mycobacterium tuberculosis with extensive resistance to second-line drugs—worldwide, 2000–2004". MMWR Morb Mortal Wkly Rep 55 (11): 301–5. 2006. PMID 16557213. http://www.cdc.gov/mmwr/preview/mmwrhtml/mm5511a2.htm.
  46. ^ Fine P, Floyd S, Stanford J, Nkhosa P, Kasunga A, Chaguluka S, Warndorff D, Jenkins P, Yates M, Ponnighaus J (2001). "Environmental mycobacteria in northern Malawi: implications for the epidemiology of tuberculosis and leprosy". Epidemiol Infect 126 (3): 379–87. doi:10.1017/S0950268801005532. PMID 11467795.
  47. ^ World Health Organization (WHO). Stop TB Partnership. Retrieved on 3 October 2006.
  48. ^ Martin C (May 2006). "Tuberculosis vaccines: past, present and future". Curr Opin Pulm Med 12 (3): 186–91. doi:10.1097/01.mcp.0000219267.27439.1b. PMID 16582673.
  49. ^ WHO statement on BCG revaccination for the prevention of tuberculosis. Geneva: World Health Organization; 1995.
  50. ^ a b Bonah C (2005). "The 'experimental stable' of the BCG vaccine: safety, efficacy, proof, and standards, 1921–1933". Stud Hist Philos Biol Biomed Sci 36 (4): 696–721. doi:10.1016/j.shpsc.2005.09.003. PMID 16337557.
  51. ^ a b Comstock G (1994). "The International Tuberculosis Campaign: a pioneering venture in mass vaccination and research". Clin Infect Dis 19 (3): 528–40. PMID 7811874.
  52. ^ Bannon M (1999). "BCG and tuberculosis". Arch Dis Child 80 (1): 80–3. doi:10.1136/adc.80.1.80. PMID 10325767.
  53. ^ WHO/UNICEF Review of National Immunization Coverage 1980–2005: South Africa (PDF). World Health Organization (August 2006). Retrieved on 2007-06-08.
  54. ^ Sadoff, Jerry. Advances in Tuberculosis Vaccine Strategies. Nature Reviews Microbiology. Vol. 4. June 2006.
  55. ^ National Institute of Allergy and Infectious Diseases (NIAID).First U.S. Tuberculosis Vaccine Trial in 60 Years Begins. National Institutes of Health News 26 January 2004. Retrieved on 19 October 2007.
  56. ^ Ha S, Jeon B, Youn J, Kim S, Cho S, Sung Y (2005). "Protective effect of DNA vaccine during chemotherapy on reactivation and reinfection of Mycobacterium tuberculosis". Gene Ther 12 (7): 634–8. doi:10.1038/sj.gt.3302465. PMID 15690060.
  57. ^ Ibanga H, Brookes R, Hill P, Owiafe P, Fletcher H, Lienhardt C, Hill A, Adegbola R, McShane H (2006). "Early clinical trials with a new tuberculosis vaccine, MVA85A, in tuberculosis-endemic countries: issues in study design". Lancet Infect Dis 6 (8): 522–8. doi:10.1016/S1473-3099(06)70552-7. PMID 16870530.
  58. ^ Doherty TM, Andersen P (October 2005). "Vaccines for Tuberculosis: Novel Concepts and Recent Progress" (PDF). Clinical Microbiology Reviews 18 (4): 687–702. doi:10.1128/CMR.18.4.687–702.2005 (inactive 2009-04-04). http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=1265910&blobtype=pdf. Retrieved on 2009-03-01.
  59. ^ "Vaccine Research - Tuberculosis". Statens Serum Institut. http://www.ssi.dk/sw13853.asp. Retrieved on 2009-03-01.
  60. ^ "Statens Serum Institut (SSI), Intercell (ICLL), and Aeras Global Tuberculosis Vaccine Foundation (Aeras) announce the initiation of a clinical trial for a novel vaccine candidate". Aeras. December 4, 2007. http://www.aeras.org/newscenter/news-detail.php?id=705. Retrieved on 2009-03-01.
  61. ^ "Vaccine Discovery — Overview". Aeras. http://www.aeras.org/our-approach/vaccine-development.php?discovery-overview. Retrieved on 2009-03-01.
  62. ^ "Tuberculosis Vaccine". Crucell. http://www.crucell.com/R_and_D-Clinical_Development-Tuberculosis_Vaccine. Retrieved on 2009-03-01.
  63. ^ Dietrich J, Andersen C, Rappuoli R, Doherty TM, Jensen CG, Andersen P (2006). "Mucosal Administration of Ag85B-ESAT-6 Protects against Infection with Mycobacterium tuberculosis and Boosts Prior Bacillus Calmette-Guérin Immunity" (PDF). Journal of Immunology 177: 6353–6360. http://www.jimmunol.org/cgi/reprint/177/9/6353.pdf. Retrieved on 2009-03-01.
  64. ^ Webber, David and Kremer, Michael. Stimulating Industrial R&D for Neglected Infectious Diseases: Economic Perspectives (PDF). Bulletin of the World Health Organization 79(8), 2001, pp. 693–801.
  65. ^ Barder, Owen; Kremer, Michael; Williams, Heidi. "Advance Market Commitments: A Policy to Stimulate Investment in Vaccines for Neglected Diseases," The Economists' Voice, Vol. 3 (2006) Issue 3.
  66. ^ Aeras Receives New Grant from the Gates Foundation
  67. ^ http://archinte.ama-assn.org/cgi/content/short/169/2/189
  68. ^ World Health Organization (WHO) WHO report 2008: Global tuberculosis control Retrieved on 13 April 2009.
  69. ^ a b World Health Organization (WHO). Global tuberculosis control - surveillance, planning, financing WHO Report 2006. Retrieved on 13 October 2006.
  70. ^ National Institute of Allergy and Infectious Diseases (NIAID). [1] 26 October 2005. Retrieved on 3 October 2006. "According to the World Health Organization (WHO), nearly 2 billion people, one-third of the world's population, have TB."
  71. ^ a b Centers for Disease Control. Fact Sheet: Tuberculosis in the United States. 17 March 2005, Retrieved on 6 October 2006.
  72. ^ Stop TB Partnership. London tuberculosis rates now at Third World proportions. PR Newswire Europe Ltd. 4 December 2002. Retrieved on 3 October 2006.
  73. ^ Iademarco MF, Castro KG (2003). "Epidemiology of tuberculosis". Seminars in respiratory infections 18 (4): 225–40. doi:10.1017/S0950268801005532. PMID 14679472.
  74. ^ Sobero R, Peabody J (2006). "Tuberculosis control in Bolivia, Chile, Colombia and Peru: why does incidence vary so much between neighbors?". Int J Tuberc Lung Dis 10 (11): 1292–5. PMID 17131791.
  75. ^ Global tuberculosis control: surveillance, planning, financing. WHO report 2007. Geneva, World Health Organization (WHO/HTM/TB/2007.376)
  76. ^ Notification rates of tuberculosis: by NHS Regional Office area, 1990-2001: Regional Trends 37 Office for National Statistics Retrieved on 13 October 2006.
  77. ^ http://gateway.nlm.nih.gov/MeetingAbstracts/ma?f=102188560.html
  78. ^ World Health Organization (WHO). Global Tuberculosis Control Report, 2006 - Annex 1 Profiles of high-burden countries. (PDF) Retrieved on 13 October 2006.
  79. ^ Centers for Disease Control and Prevention (CDC). 2005 Surveillance Slide Set. (12 September 2006) Retrieved on 13 October 2006.
  80. ^ Chaisson RE, Martinson NA (2008). "Tuberculosis in Africa—combating an HIV-driven crisis". N Engl J Med 358 (11): 1089–1092. doi:10.1056/NEJMp0800809. PMID 18337598. http://content.nejm.org/cgi/content/full/358/11/1089?query=TOC.
  81. ^ Davies PDO, Yew WW, Ganguly D, et al. (2006). "Smoking and tuberculosis: the epidemiological association and pathogenesis". Trans R Soc Trop Med Hyg 100: 291–8. doi:10.1016/j.trstmh.2005.06.034. PMID 16325875.
  82. ^ Jha P, Jacob B, Gajalakshmi V, et al. (2008). "A nationally representative case–control study of smoking and death in India". N Engl J Med 358 (11): 1137–1147. doi:10.1056/NEJMsa0707719. PMID 18272886. http://content.nejm.org/cgi/content/full/358/11/1137?query=TOC.
  83. ^ Restrepo BI (August 2007). "Convergence of the tuberculosis and diabetes epidemics: renewal of old acquaintances". Clin. Infect. Dis. 45 (4): 436–8. doi:10.1086/519939. PMID 17638190.
  84. ^ a b Strachan DP, Powell KJ, Thaker A, Millard FJ, Maxwell JD (1995-02). "Vegetarian diet as a risk factor for tuberculosis in immigrant south London Asians". Thorax 50 (2): 175–80. doi:10.1136/thx.50.2.175. PMID 7701458.
  85. ^ Davis L (August 1995). "Vegetarian diet and tuberculosis in immigrant Asians". Thorax 50 (8): 915–6. doi:10.1136/thx.50.8.915-c. PMID 7570453. PMC: 474924. http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=474924&blobtype=pdf.
  86. ^ Ustianowski A, Shaffer R, Collin S, Wilkinson RJ, Davidson RN (June 2005). "Prevalence and associations of vitamin D deficiency in foreign-born persons with tuberculosis in London". The Journal of infection 50 (5): 432–7. doi:10.1016/j.jinf.2004.07.006. PMID 15907552.
  87. ^ Nnoaham KE, Clarke A (February 2008). "Low serum vitamin D levels and tuberculosis: a systematic review and meta-analysis". International journal of epidemiology 37 (1): 113–9. doi:10.1093/ije/dym247. PMID 18245055.
  88. ^ Schaible UE, Kaufmann SH (May 2007). "Malnutrition and infection: complex mechanisms and global impacts". PLoS medicine 4 (5): e115. doi:10.1371/journal.pmed.0040115. PMID 17472433. PMC: 1858706. http://medicine.plosjournals.org/perlserv/?request=get-document&doi=10.1371/journal.pmed.0040115.
  89. ^ Lönnroth K, Raviglione M (October 2008). "Global epidemiology of tuberculosis: prospects for control". Seminars in respiratory and critical care medicine 29 (5): 481–91. doi:10.1055/s-0028-1085700. PMID 18810682.
  90. ^ Davies PD (2003). "The world-wide increase in tuberculosis: how demographic changes, HIV infection and increasing numbers in poverty are increasing tuberculosis". Annals of medicine 35 (4): 235–43. doi:10.1080/07853890310005713. PMID 12846265.
  91. ^ Spence DP, Hotchkiss J, Williams CS, Davies PD (September 1993). "Tuberculosis and poverty". BMJ (Clinical research ed.) 307 (6907): 759–61. doi:10.1136/bmj.307.6907.759. PMID 8219945. PMC: 1696420. http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=1696420&blobtype=pdf.
  92. ^ Rothschild B, Martin L, Lev G, Bercovier H, Bar-Gal G, Greenblatt C, Donoghue H, Spigelman M, Brittain D (2001). "Mycobacterium tuberculosis complex DNA from an extinct bison dated 17,000 years before the present". Clin Infect Dis 33 (3): 305–11. doi:10.1086/321886. PMID 11438894.
  93. ^ Pearce-Duvet J (2006). "The origin of human pathogens: evaluating the role of agriculture and domestic animals in the evolution of human disease". Biol Rev Camb Philos Soc 81 (3): 369–82. doi:10.1017/S1464793106007020. PMID 16672105.
  94. ^ Ernst JD, Trevejo-Nuñez G, Banaiee N (July 2007). "Genomics and the evolution, pathogenesis, and diagnosis of tuberculosis". J. Clin. Invest. 117 (7): 1738–45. doi:10.1172/JCI31810. PMID 17607348.
  95. ^ Hershkovitz I, Donoghue HD, Minnikin DE, Besra GS, Lee OY-C, et al. (15 October 2008). "Detection and Molecular Characterization of 9000-Year-Old Mycobacterium tuberculosis from a Neolithic Settlement in the Eastern Mediterranean.". PLoS ONE 3 (10): e3426. doi:10.1371/journal.pone.0003426.
  96. ^ Zink A, Sola C, Reischl U, Grabner W, Rastogi N, Wolf H, Nerlich A (2003). "Characterization of Mycobacterium tuberculosis complex DNAs from Egyptian mummies by spoligotyping". J Clin Microbiol 41 (1): 359–67. doi:10.1128/JCM.41.1.359-367.2003. PMID 12517873.
  97. ^ Hippocrates. Aphorisms. Accessed 7 October 2006.
  98. ^ Konomi N, Lebwohl E, Mowbray K, Tattersall I, Zhang D (2002). "Detection of mycobacterial DNA in Andean mummies". J Clin Microbiol 40 (12): 4738–40. doi:10.1128/JCM.40.12.4738-4740.2002. PMID 12454182.
  99. ^ "South America: Prehistoric Findings". Memorias do Instituto Oswaldo Cruz, Vol. 98 (Suppl.I) January 2003. Retrieved on 2007-02-08.
  100. ^ Sledzik P, Bellantoni N (1994). "Brief communication: bioarcheological and biocultural evidence for the New England vampire folk belief". Am J Phys Anthropol 94 (2): 269–74. doi:10.1002/ajpa.1330940210. PMID 8085617. http://users.net1plus.com/vyrdolak/tableone.htm.
  101. ^ a b Katharine Briggs, An Encyclopedia of Fairies "Consumption" (Pantheon Books, 1976) p. 80. ISBN 0-394-73467-X
  102. ^ Lawlor, Clark. "Transatlantic Consumptions: Disease, Fame and Literary Nationalism in the Davidson Sisters, Southey, and Poe". Studies in the Literary Imagination, Fall 2003. Available at findarticles.com. Retrieved on 2007-06-08.
  103. ^ Laumann, Edward O. (1994) The Social Organization of Sexuality: Sexual Practices in the United States University of Chicago Press p 80, ISBN 0-22647-020-2
  104. ^ Y. A. Al-Sharrah (2003), "The Arab Tradition of Medical Education and its Relationship with the European Tradition", Prospects 33 (4), Springer.
  105. ^ George Sarton, Introduction to the History of Science.
    (cf. Dr. A. Zahoor and Dr. Z. Haq (1997). Quotations From Famous Historians of Science, Cyberistan.)
  106. ^ David W. Tschanz, MSPH, PhD (August 2003). "Arab Roots of European Medicine", Heart Views 4 (2).
  107. ^ Pliny the Elder, Natural History, quoted at Naphtali Lewis, Meyer Reinhold. "Roman Civilization". http://books.google.com/books?id=GO8tcTpgj-0C.
  108. ^ Who Named It? Léon Charles Albert Calmette. Retrieved on 6 October 2006.
  109. ^ Trail R (1970). "Richard Morton (1637–1698)". Med Hist 14 (2): 166–74. PMID 4914685.
  110. ^ Zur Pathogenie der Impetigines. Auszug aus einer brieflichen Mitteilung an den Herausgeber. [Müller’s] Archiv für Anatomie, Physiologie und wissenschaftliche Medicin. 1839, page 82.
  111. ^ Kentucky: Mammoth Cave long on history. CNN. 27 February 2004. Accessed 8 October 2006.
  112. ^ a b c McCarthy OR (2001). "The key to the sanatoria". J R Soc Med 94 (8): 413–7. PMID 11461990.
  113. ^ Nobel Foundation. The Nobel Prize in Physiology or Medicine 1905. Accessed 7 October 2006.
  114. ^ Waddington K (2004). "To stamp out "so terrible a malady": bovine tuberculosis and tuberculin testing in Britain, 1890–1939". Med Hist 48 (1): 29–48. PMID 14968644.
  115. ^ Torrey EF and Yolken RH. 2005. Their bugs are worse than their bite. Washington Post, April 3, p. B01.
  116. ^ Medical Research Council (UK). MRC's contribution to Tuberculosis research. Accessed 2 July 2007.
  117. ^ Wolfart W (1990). "Surgical treatment of tuberculosis and its modifications—collapse therapy and resection treatment and their present-day sequelae". Offentl Gesundheitswes 52 (8–9): 506–11. PMID 2146567.
  118. ^ Lalloo U, Naidoo R, Ambaram A (2006). "Recent advances in the medical and surgical treatment of multi-drug resistant tuberculosis". Curr Opin Pulm Med 12 (3): 179–85. doi:10.1097/01.mcp.0000219266.27439.52. PMID 16582672.
  119. ^ "Tuberculosis — Respiratory and Non-respiratory Notifications, England and Wales, 1913-2005". Health Protection Agency Centre for Infections. 21 March 2007. http://www.hpa.org.uk/infections/topics_AZ/tb/epidemiology/table1.htm. Retrieved on 2007-08-01.
  120. ^ Paolo W, Nosanchuk J (2004). "Tuberculosis in New York city: recent lessons and a look ahead". Lancet Infect Dis 4 (5): 287–93. doi:10.1016/S1473-3099(04)01004-7. PMID 15120345.
  121. ^ World Health Organization (WHO). Frequently asked questions about TB and HIV. Retrieved 6 October 2006.
  122. ^ Tweddle N, Livingstone P (1994). "Bovine tuberculosis control and eradication programs in Australia and New Zealand". Vet Microbiol 40 (1–2): 23–39. doi:10.1016/0378-1135(94)90044-2. PMID 8073626.
  123. ^ The Department of Agriculture & Food (Ireland). Disease Eradication Schemes - Bovine Tuberculosis and Brucellosis. Retrieved on 8 May 2006.
  124. ^ Cassidy, Martin. Badgers targeted over bovine TB. BBC News 2 December 2004. Retrieved on 8 May 2006.
  125. ^ National Federation of Badger Groups (Ireland). Cattle blamed for massive increase in bovine TB. Retrieved on 8 May 2006.
  126. ^ "Badgers and cattle TB: the final report of the Independent Scientific Group on Cattle TB" (PDF). House of Commons Environment, Food and Rural Affairs Committee. http://www.publications.parliament.uk/pa/cm200708/cmselect/cmenvfru/130/130i.pdf. Retrieved on 2008-07-04.
  127. ^ "Farmers' anger on cull rejection". BBC News. 4 July 2008. http://news.bbc.co.uk/2/hi/uk_news/england/7489413.stm. Retrieved on 2008-07-04.

Further reading

Source : http://en.wikipedia.org/wiki/Tuberculosis

1 comment:

  1. I started on COPD Herbal treatment from Ultimate Health Home, the treatment worked incredibly for my lungs condition. I used the herbal treatment for almost 4 months, it reversed my COPD. My severe shortness of breath, dry cough, chest tightness gradually disappeared. Reach Ultimate Health Home via their email at ultimatehealthhome@gmail.com . I can breath much better and It feels comfortable!

    ReplyDelete