View clinical trials related to Latent Tuberculosis.
Filter by:This is a multicenter, prospective observational cohort study, in which patients with chronic airway diseases including chronic obstructive pulmonary disease(COPD), asthma, asthma-COPD overlap syndrome (ACOS) will be recruited.
This study will assess the next generation of blood tests for latent TB infection, which may be able to indicate how treatment is working as well as in diagnosis infection.
Tuberculosis (TB) control remains a public health challenge. Many people in the UK do not have a general practitioner (GP) registration and their only interaction with the NHS is via Accident and Emergency (A&E) Departments of hospitals. This is often the case for those in hard to reach groups, who are also those often at highest risk of TB. This study seeks to assess whether A&E Departments are effective sites for the identification and onward management of TB, both in its latent and active forms.
To evaluate CT abnormalities in the lung parenchyma in close contacts at high risk for developing multidrug- or extensively drug-resistant Tb by using a follow-up ultralow dose CT scan.
The goal of this clinical trial is to determine whether vitamin D supplementation reduces risk of acquiring latent tuberculosis infection (LTBI) in school age children in Mongolia. The investigators hypothesize that (1) vitamin D supplementation will reduce risk of acquisition of LTBI, (2) vitamin D supplementation will safely reduce risk of developing active TB and improve other secondary efficacy outcomes, and (3) children with the lowest vitamin D status at baseline will gain most from the intervention.
Background: Tuberculosis (TB) is a severe disease and a major cause of death in many people worldwide. It is caused by a bacteria that enters through the lungs and can spread elsewhere in the body. People with latent TB have the bacteria that lie dormant but can become active and cause disease. These people are offered treatment to prevent development of active TB. Worldwide, a lot of people with LTBI also have a parasitic worm called a helminth that can stay in the gut or the blood. These parasites can affect the immune system and cause diseases like TB to become worse. Researchers want to see how helminth infection makes it harder for people to fight TB infection. Objectives: - To study how the immune system of people with latent tuberculosis infection (LTBI) acts to prevent development of active TB. Also, to study how helminth infection might affect this immune response. Eligibility: - Adults age 18 70 with LTBI as defined by an approved blood test called QuantiFERON TB Gold. - No evidence of infections like Hepatitis or HIV - Pregnant subjects and subjects taking medications that suppress the immune system are not eligible. - Have not received prior treatment for LTBI. Participants might be still eligible if prior treatment for active TB has been received Design: Screening phase: - Participants will be screened with medical history, physical exam, and blood tests for other infections/conditions which might affect the immune system. They will have testing for active TB i.e. blood testing as well as testing of their spit, scans and X-rays. Baseline phase: - Only eligible participants will be entered into the study. - Participants will have interviews, medical history, and physical exam. - Blood will be drawn from an arm vein for testing. - Participants will collect stool samples at home for 3 days in a row to test for helminth infection.. - Participants may have apheresis. Blood cells are removed by needle. They pass through a separator machine which returns everything but the cells back to the participant. - Participants may have procedures at the start and end of the study that let researchers look into the lungs and collect cells. Study phase, about 2 years: - All participants will be offered treatment for LTBI which lasts 6-9 months. - Participants being treated for LTBI will have about 11 study visits. They will visit monthly for 9 months while on treatment, then 6 and 12 months after treatment. - Participants not eligible/refusing treatment for LTBI will be made aware of active TB, then have 3 other visits, about 6, 12, and 24 months after the baseline visit. - Participants who have helminth infection will receive appropriate treatment. - All participants will have blood drawn at each visit.
Background: Tuberculosis (TB) remains the most important infectious disease in the world. Keys to successful control of TB is rapid diagnosis, prompt treatment, as well as effective preventive therapy for contacts with latent TB infection (LTBI). Current methods for the diagnosis of LTBI are tuberculin skin test (TST) and interferon-gamma release assay (IGRA). For preventive therapy, the recommended regimens include daily isoniazid for 9 months and daily rifampicin for 4 months. By incorporating long-acting rifapentine, a new regimen combining weekly rifapentine and high-dose isoniazid for a total of 12 doses has been proven of equal potency and toxicity. However, the treatment completion rate is much higher in weekly treatment for 3 months than daily treatment for 9 months. It is reasonable that using rifapentine-based preventive therapy can markedly increase the completion rate. However, study is lacking, especially in Asia, the high endemic area of TB. With the effort of all health care workers and public health personnel, the incidence of TB in Taiwan has gradually declined in recent 10 years. In order to maintain the trend of decreasing in incidence, preventive therapy for LTBI become more and more important. However, which is the best preventive regimen for LTBI is still unknown. Therefore, we conduct the prospective randomized multicenter studies to compare the treatment completion rate of two regimens in Taiwan. The first regimen is daily isoniazid for 9 months. The second is weekly rifapentine plus high-dose isoniazid for 3 months.
The purpose of this study is to use a cluster randomized trial to compare the effectiveness of linking the Quantiferon-gold in-tube test (QGIT) with routine CD4 testing to the routine use of the tuberculin skin test (TST), the current standard of care for diagnosing latent tuberculosis infection (LTBI) in South Africa. The investigators hypothesize that QGIT clinics will identify LTBI and initiate isoniazid preventive therapy (IPT) in a higher proportion of patients and in a significantly faster timeframe. The cost-effectiveness of linking QGIT with routine CD4 compared to routine TST will also be evaluated, and the process of implementation of QGIT into the routine cluster of differentiation 4 (CD4) blood draw will be evaluated using a mixed method approach to identify steps that can be modified for future scale-up of the intervention.
The investigators propose the development of a range of nasal spray challenge models to study the way the nose can respond to different types of nasal challenge that elicit different forms of inflammation. The investigators will carry out nasal challenge with bacterial and viral components and allergens. In this way the nasal upper respiratory tract mucosa is challenged with stimuli of the immune system, causing various types of inflammation. Samples will be taken by blotting the nostril surface and by scraping off tiny surface samples. The nose will be sprayed with a substance that is a single part of a bacteria or virus, or with an allergen. The material delivered by nasal spray is of high purity and is sterile, containing no live bacteria or viruses. The nasal spray substance contains molecular patterns that are recognised as foreign by the immune system, and at the right dose should stimulate the immune system, causing mild nasal inflammation. The study employs noninvasive methods of sampling using absorptive strips. These strips look and feel like tissue paper, and are applied to each nostril for a period of 1 min. A few pinhead-sized tissue samples are taken from inside the nose, using a small disposable sterile plastic probe that has a tiny scoop on its end. In the nasal lining fluid and tissue samples, measurement will taken of a range of molecules and cells that protect against infections and help the immune response. By spraying the nose with a challenge agent in this manner, the nasal immune response can be assessed, which can help us better understand how the human immune system cells and molecules respond to bacteria and viruses. In the future, this may allow the testing of new drugs and vaccines, by seeing if they decrease or stop the inflammation after the nasal challenge.
The aim of study is to evaluate the prevalence of latent TB in second generation immigrants from countries with high incidence of tuberculosis (above 20 of 100,000) compare to the control native Israelis without a family member who was born in a country with high incidence of tuberculosis. Using study questionnaire IGRA and tuberculin skin test the investigators expect that the second generation immigrants group will have more positive IGRA test than the control native group.