Tuberculosis pathophysiology

Revision as of 19:02, 18 September 2017 by WikiBot (talk | contribs) (Changes made per Mahshid's request)
Jump to navigation Jump to search
https://https://www.youtube.com/watch?v=yR51KVF4OX0%7C350}}

Tuberculosis Microchapters

Home

Patient Information

Overview

Historical Perspective

Classification

Pathophysiology

Causes

Differentiating Tuberculosis from other Diseases

Epidemiology and Demographics

Risk Factors

Screening

Natural History, Complications and Prognosis

Children

HIV Coinfection

Diagnosis

History and Symptoms

Physical Examination

Laboratory Findings

Electrocardiogram

Chest X Ray

CT

MRI

Echocardiography or Ultrasound

Other Imaging Findings

Other Diagnostic Studies

Treatment

Medical Therapy

Special Conditions
Drug-resistant

Surgery

Primary Prevention

Secondary Prevention

Cost-Effectiveness of Therapy

Future or Investigational Therapies

Case Studies

Case #1

Tuberculosis pathophysiology On the Web

Most recent articles

Most cited articles

Review articles

CME Programs

Powerpoint slides

Images

American Roentgen Ray Society Images of Tuberculosis pathophysiology

All Images
X-rays
Echo & Ultrasound
CT Images
MRI

Ongoing Trials at Clinical Trials.gov

US National Guidelines Clearinghouse

NICE Guidance

FDA on Tuberculosis pathophysiology

CDC on Tuberculosis pathophysiology

Tuberculosis pathophysiology in the news

Blogs on Tuberculosis pathophysiology

Directions to Hospitals Treating Tuberculosis

Risk calculators and risk factors for Tuberculosis pathophysiology

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: João André Alves Silva, M.D. [2]

Overview

M. tuberculosis is acquired by inhaled aerosols produced by patients with active disease. The mycobacterium thrives in the upper lung lobes given the high oxygen content. Tuberculosis is a prototypical granulomatous infection. The granuloma prevents the dissemination of mycobacteria and provides a pathway for immune cell communication. Within the granuloma, CD4 T lymphocytes secrete cytokines such as interferon gamma that activate local macrophages.

Pathogenesis

The M. tuberculosis bacterium is acquired by inhaled aerosols generated by individuals with active pulmonary disease. They travel to the terminal airways and alveoli (commonly at the middle lobes, upper regions of lower lobes and lower regions of upper lobes) and are phagocytosed by alveolar macrophages. The initial immune response generated by these macrophages recruits further macrophages, neutrophils, and monocytes, leading to primary containment of the bacilli. Despite having a very low infectious dose (ID<200 bacteria), 90% of immunocompetent individuals that acquire M. tuberculosis do not develop symptoms. In most cases, the bacteria may either be eliminated, or be harbored in a latent state by an immune formation known as a granuloma. The granuloma is a structured, radial aggregation of immune cells that prevents the dissemination of mycobacteria and provides a pathway for immune cell communication.[1] The initial focus of infection in the lung is a single region in 75% of the cases, and is called the Ghon focus. Besides the alveolar macrophages, other immune cells such as blood monocytes (tissue macrophages) and lymphocytes also migrate to the Ghon focus aiding in the termination of the infection or initiation of a granulomatous containment.[1][2]

Primary Infection

In an immunocompetent person, the infected macrophages are transported through the lymph to the regional lymph nodes. In immunocompromised patients, these macrophages may reach different parts of the body, through the bloodstream. Despite this wide initial dissemination, most patients resolve those foci of infection without any signs or symptoms of disease. However, during the dissemination of the infected macrophages, tissues that are more prone to bacterial replication, represent potential metastatic foci. These tissues include:[1][2]

Although all parts of the body can be affected by TB, the heart, skeletal muscles, pancreas and thyroid are rarely affected.[3] In a small number of cases, when there is a large concentration of antigens in the primary focus, the development of the immune response and hypersensitivity may lead to the necrosis and calcification of this infection site. These primary calcified foci are called Ranke complex.[1][4]

Progression of the Primary Infection

Initial foci of infection may evolve into large pulmonary lymph nodes. These may lead to:[1]

More commonly in non-caucasian children, with inferior resistance to tuberculosis, the primary focus of infection may evolve to constitute progressive primary disease, with advancing pneumonia. The infection may lead to the formation of cavitations with spread of the infection through the bronchi. This may also occur in HIV and elderly patients.[1][5][6] In young children, the dissemination of infection before the onset of hypersensitivity may lead to military tuberculosis. Bacteria may disseminate directly from the primary focus, or from the Weigart focus (metastatic focus adjacent to a pulmonary vein) through the blood.[1][7] In younger patients, serofibrinous pleurisy is more prone to occur following the rupture of subpleural foci of infection into the pleural space.[1] The most severe consequence of the dissemination of bacteria from primary or metastatic foci, through the blood and lymph, is the seeding of the postero-apical regions of the lung. Here bacteria are able to replicate without the opposition of the immune system, potentially leading pulmonary tuberculosis.[1]

Immunopathogenesis

The immune response against tuberculosis consists of both innate and acquired systems, with cell-mediated immunity predominating over humoral immunity.

Innate Immune Response

The immune response against M. tuberculosis is minimal during the first weeks, allowing it to replicate in the alveolar spaces and macrophages, constituting the Ghon focus, or metastatic foci. Recognition and phagocytosis of the M. tuberculosis bacilli occurs via the following receptors on macrophages:[8]

  • Toll-like Receptor 2 (TLR2)
  • TLR4
  • TLR9
  • Dectin-1
  • DC-SIGN
  • Mannose receptor
  • Complement receptors
  • NOD2

Acquired Immunity and Granuloma Formation

Although the granuloma creates an immune microenvironment in which the infection can be controlled, it also provides the mycobacterium with a niche in which it can survive. Within the granuloma, the bacilli can modulate the immune response to ensure their survival over long periods of time. One of the most important factors required for the establishment of infection is a balance between the pro-inflammatory and anti-inflammatory cytokines produced to reduce or control bacterial proliferation. TNF-α and IFN-γ are particularly important in promoting the formation and function of the granuloma, whereas IL-10 is one of the main negative regulators of this response. The granuloma contains mostly blood-derived macrophages, epithelioid cells (differentiated macrophages) and multinucleated giant cells (also known as Langhans giant cells), surrounded by T lymphocytes. Caseous granulomas are typical of tuberculosis. These structures are formed by epithelioid macrophages surrounding a cellular necrotic region with a rim of lymphocytes of the T- and B-cell types. Other types of granuloma include nonnecrotising granulomas, which consist primarily of macrophages with a few lymphocytes, necrotic neutrophilic granulomas, and completely fibrotic granulomas.[9]

Many different chemokines are involved in granuloma formation . Some are produced by the epithelial cells of the respiratory tract, and others are produced by the immune cells themselves. In particular, the chemokines binding to the CCR2 receptor (CCL2/MCP-1, CCL12, and CCL13) are important for the early recruitment of macrophages. Osteopontin, which is produced by macrophages and lymphocytes, promotes the adhesion and recruitment of these cells. CCL19 and, possibly, CCL21 are involved in the recruitment and priming of IFN--producing T cells. CXCL13 is involved in B-cell recruitment and the formation of follicular structures. The expression of the CC and CXC chemokines is deregulated at the transcriptional level in TNF-deficient mice, and the lack of these chemokines prevents the recruitment of macrophages and CD4+ T cells, accounting for the critical role of TNF- in granuloma formation.[9]

Following inhalation of contaminated aerosols, M. Tuberculosis moves to the lower respiratory tract where it is recognized by alveolar macrophages. This recognition is mediated by a set of surface receptors (see text), which drive the uptake of the bacteria and trigger innate immune signalling pathways leading to the production of various chemokines and cytokines (a). Epithelial cells and neutrophils can also produce chemokines in response to bacterial products (not represented). This promotes recruitment of other immune cells (more macrophages, dendritic cells, and lymphocytes) to the infection site (b). They organise in a spherical structure with infected macrophages in the middle surrounded by various categories of lymphocytes (mainly CD4+, CD8+, and γ/δ T cells). Macrophages (MP) can fuse to form MGCs or differentiate into lipid-rich foamy cells (FM). B lymphocytes tend to aggregate in follicular-type structures adjacent to the granuloma ((c), see text for details). The bacteria can survive for decades inside the granuloma in a latent state. Due to some environmental (e.g., HIV infection, malnutrition etc.) or genetic factors, the bacteria will reactivate and provoke the death of the infected macrophages. A necrotic zone (called caseum due to its milky appearance) will develop in the centre of the granuloma (d). Ultimately the structure will disintegrate allowing exit of the bacteria, which will spread in other parts of the lungs and more lesions will be formed. Infection will also be transmitted to other individuals due to release of the infected droplets by coughing (e).[9]

Molecular Pathogenesis

  • Alveolar macrophages and dendritic cells present mycobacterial antigens on their surfaces through class II major histocompatibility complex. These antigens will be recognized by CD4 lymphocytes through αβ T-cell receptors. CD4 lymphocytes, once activated, release lymphokines that attract more macrophages to the site of infection.
  • Interferon gamma (IFN-γ) and tumor necrosis factor alpha (TNF-α) signaling activates further macrophages which engulf the tuberculosis bacilli. [10]
  • Metalloproteinase converts the transmembrane protein to soluble TNF-α. This binds with the receptor TNFR1 and TNFR2 and through caspase dependant pathways induce apoptosis.
  • TNF along with the synergistic action of interferon gamma increases the phagocytic activity of the macrophages and causes the intracellular killing of the pathogens by reactive nitrogen and oxygen intermediates.
  • Neutralization of the TNF-α activity causes the persistence of mycobacterial activities within the granuloma in latent infection.Thus they are required for the formation and maintanence of granuloma in tuberculosis.
  • TNF stimulates the production of CCL2, CCL3, CCL4, CCL5, CCL8 cytokines and increases CD54 causing focussed accumulation of immune cells and plays a pivotal role in the generation of granuloma and maintaining the integrity of the granuloma. [10]
  • During lymphocyte activation, immune cells produce large amounts of lytic enzymes, which when released, lead to the necrosis of tissues.


[(http://en.wikipedia.org/wiki/Tumor_necrosis_factor_alpha#mediaviewer/File:TNF_signaling.jpg)][11]

Once within alveolar macrophages, M. tuberculosis uses multiple mechanisms in order to survive:[1]

Transmission

After contact with a patient that has the active form of the disease, and inhalation of the M. tuberculosis the risk of developing active tuberculosis is low, with a life-time projected risk of about 10%.[12] The probability of transmission from one person to another depends on the number of infectious droplets expelled by the carrier, the effectiveness of ventilation, the duration of the exposure, and the virulence of the strain of M. tuberculosis.[13] The probability of transmitting the disease is highest during the first years, after the person has been infected, decreasing hence forth.[14]

In rare occasions, the bacteria may be transmitted through other routes, besides the pulmonary. In these cases, the formation of foci in local lymph nodes is always involved. These alternative routes of transmission include:[1]

Associated Conditions

AIDS

Tuberculosis influences the progression of HIV replication in infected patients, leading to an increase in the mortality rate.[15]

On the other hand, HIV infected patients, particularly those with low counts of CD4 lymphocytes, have increased risk of reactivation of latent tuberculosis. Additionally, when recently infected with M. tuberculosis, these patients tend to rapidly progress into active disease.[1][16][17] It is still not known if AIDS influences the risk of infection, when in contact with the M. tuberculosis.[1]

Patients with AIDS have increased risk of developing pulmonary and extrapulmonary tuberculosis. Extrapulmonary disease in this group of patients has characteristic manifestations, such as:[1]

Gallery

References

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 Mandell, Gerald (2010). Mandell, Douglas, and Bennett's principles and practice of infectious diseases. Philadelphia, PA: Churchill Livingstone/Elsevier. ISBN 0443068399.
  2. 2.0 2.1 Herrmann J, Lagrange P (2005). "Dendritic cells and Mycobacterium tuberculosis: which is the Trojan horse?". Pathol Biol (Paris). 53 (1): 35–40. PMID 15620608.
  3. Agarwal R, Malhotra P, Awasthi A, Kakkar N, Gupta D (2005). "Tuberculous dilated cardiomyopathy: an under-recognized entity?". BMC Infect Dis. 5 (1): 29. PMID 15857515.
  4. Grosset J (2003). "Mycobacterium tuberculosis in the extracellular compartment: an underestimated adversary". Antimicrob Agents Chemother. 47 (3): 833–6. PMID 12604509.
  5. Stead WW, Lofgren JP, Warren E, Thomas C (1985). "Tuberculosis as an endemic and nosocomial infection among the elderly in nursing homes". N Engl J Med. 312 (23): 1483–7. doi:10.1056/NEJM198506063122304. PMID 3990748.
  6. Murray JF (1990). "Cursed duet: HIV infection and tuberculosis". Respiration. 57 (3): 210–20. PMID 2274719.
  7. 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.
  8. Aderem A, Underhill DM (1999). "Mechanisms of phagocytosis in macrophages". Annu Rev Immunol. 17: 593–623. doi:10.1146/annurev.immunol.17.1.593. PMID 10358769.
  9. 9.0 9.1 9.2 Silva Miranda M, Breiman A, Allain S, Deknuydt F, Altare F (2012). "The tuberculous granuloma: an unsuccessful host defence mechanism providing a safety shelter for the bacteria?". Clin Dev Immunol. 2012: 139127. doi:10.1155/2012/139127. PMC 3395138. PMID 22811737.
  10. 10.0 10.1 "Tumor Necrosis Factor alpha".
  11. "TNF Alpha". Missing or empty |url= (help)
  12. Glaziou P, Falzon D, Floyd K, Raviglione M (2013). "Global epidemiology of tuberculosis". Semin Respir Crit Care Med. 34 (1): 3–16. doi:10.1055/s-0032-1333467. PMID 23460002.
  13. "Causes of Tuberculosis". Mayo Clinic. 2006-12-21. Retrieved 2007-10-19.
  14. Lawn SD, Zumla AI (2011). "Tuberculosis". Lancet. 378 (9785): 57–72. doi:10.1016/S0140-6736(10)62173-3. PMID 21420161.
  15. Zumla A, Raviglione M, Hafner R, von Reyn CF (2013). "Tuberculosis". N Engl J Med. 368 (8): 745–55. doi:10.1056/NEJMra1200894. PMID 23425167.
  16. Daley CL, Small PM, Schecter GF, Schoolnik GK, McAdam RA, Jacobs WR; et al. (1992). "An outbreak of tuberculosis with accelerated progression among persons infected with the human immunodeficiency virus. An analysis using restriction-fragment-length polymorphisms". N Engl J Med. 326 (4): 231–5. doi:10.1056/NEJM199201233260404. PMID 1345800.
  17. Bouvet E, Casalino E, Mendoza-Sassi G, Lariven S, Vallée E, Pernet M; et al. (1993). "A nosocomial outbreak of multidrug-resistant Mycobacterium bovis among HIV-infected patients. A case-control study". AIDS. 7 (11): 1453–60. PMID 8280411.
  18. Shafer RW, Kim DS, Weiss JP, Quale JM (1991). "Extrapulmonary tuberculosis in patients with human immunodeficiency virus infection". Medicine (Baltimore). 70 (6): 384–97. PMID 1956280.
  19. Meintjes G, Lawn SD, Scano F, Maartens G, French MA, Worodria W; et al. (2008). "Tuberculosis-associated immune reconstitution inflammatory syndrome: case definitions for use in resource-limited settings". Lancet Infect Dis. 8 (8): 516–23. doi:10.1016/S1473-3099(08)70184-1. PMC 2804035. PMID 18652998.
  20. 20.0 20.1 20.2 20.3 20.4 20.5 20.6 20.7 20.8 "Public Health Image Library (PHIL), Centers for Disease Control and Prevention".

Template:WH Template:WS

Retrieved from "https://www.wikidoc.org/index.php?title=Tuberculosis_pathophysiology&oldid=1360258"