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Posts in ‘macrophages’

TB Treatment For Elderly Likely Requires Boost To Immune Response

Aug 28

*ScienceDaily (June 12, 2008) — Manipulating the immune system in elderly people appears to be the most likely way to help older patients wage an effective battle against tuberculosis, a new study suggests.

Mathematical modeling of how mice respond to TB infection suggests that potential therapy options for elderly TB patients could either increase their white blood cell count or enhance infected cells’ interaction with their immune system.

Simulations of TB infection in an old mouse showed that increasing the number of infection-fighting white blood cells, called CD4 T cells, could be particularly effective at bolstering the mouse’s immune response, which naturally slows with aging. Older humans have similar delays in their immune response, meaning that they have a much more difficult time controlling TB than do younger people with an active infection.

The math modeling also suggested that making changes to macrophages, cells that essentially eat infecting bacteria, could enhance those cells’ interactions with other warriors in the immune system, reducing the concentration of bacteria in the lungs associated with TB infection.

Both findings suggest potential strategies for development of vaccines or treatments specifically for elderly TB patients, said Joanne Turner, lead author of the study and an assistant professor of internal medicine at Ohio State University.

“This modeling is giving us clues as to what would help an older person control infection,” Turner said. “In thinking about therapies, if we find a way to make older people have a better T-cell response, such as with vaccination, or by giving them a post-exposure therapy in the lung that would activate the macrophage better, either way they should be able to control infection more effectively.”

About 2 billion people worldwide are thought to be infected with TB bacteria, Mycobacterium tuberculosis. People who are infected can harbor the bacterium without symptoms for decades, but an estimated one in 10 will develop active disease characterized by a chronic cough and chest pain. In the United States, the Centers for Disease Control and Prevention reported 14,093 active cases of TB in 2005. Another 10 to 15 million people in the United States are believed to have latent TB. An active infection is treated with a combination of antibiotics that patients take for at least six months.

The elderly are considered highly susceptible to both reactivation of latent TB infection and newly acquired infections, especially in long-term care facilities, where people are generally sicker and transmission can occur more rapidly. Many older patients cannot tolerate the antibiotic regimen required to treat active TB.

For this line of research, Turner has turned to mathematical modeling to test various scenarios in an old mouse’s immune response to infection with the TB pathogen. The modeling allows researchers to simulate outcomes resulting from multiple tweaks to assumptions about immune response activities. Outcomes in a young mouse model are used for comparison. The findings can be verified later in highly targeted animal studies.

The immune response to TB infection is complex, and aging affects that process. In fighting infections, two immune responses occur: The innate immune response begins a fight against any pathogen. The acquired immune response follows, with components designed to fight the specific pathogen causing the infection.

Older people, and mice, have a strong innate immune response that enables them to initially control bacteria from TB and other infectious diseases.

“But you absolutely have to have an acquired immune response to control TB infection, and that’s where the old mice do poorly. They generate that very slowly, giving the bacteria time to grow to higher levels in the lung,” said Turner, also an investigator in Ohio State’s Center for Microbial Interface Biology.

At the point of infection, TB bacteria are absorbed by a macrophage, also called an antigen-presenting cell. The macrophage activates specific molecules that make pieces of the bacteria visible to the infection-fighting T cells, which triggers an eventual T-cell response to come to the macrophage’s aid.

“These bacteria are very smart, and they find ways to hide from the immune system. So you have a delay before the T cells can see the infection, allowing the bacteria to grow fairly unrestricted in the lung to quite a high number,” Turner said.

Eventually, during the acquired immune response, T cells that are specific for TB infection are generated and travel to the lung to help the macrophages. These CD4 T cells secrete a substance called interferon gamma, which activates the macrophage to help it kill the bacteria.

If the immune response fails to prompt macrophages to kill the TB bacteria, the infected macrophages eventually burst and release TB bacteria into the lungs.

For this work, Turner and Barbara Szomolay, a postdoctoral researcher in Ohio State’s Mathematical Biosciences Institute and a study co-author, set up a model that would allow them to alter assumptions with hopes of trying to improve an old mouse’s acquired immune response. Szomolay assembled multiple equations to allow for variations in quantities of T cells, specialized molecules, macrophages and bacteria counts, as well as related substances that trigger certain immune functions.

The two most effective methods found to improve infection control in the old mouse model were increasing the number of CD4 T cells present early on in the infection, and increasing the number of specialized molecules on the surface of macrophages, enhancing the visibility of the TB bacteria.

“We showed that we could change the control of infection, but we could never get that old mouse to look like a young mouse, which means that there’s more to the immune system defect than just the initial interaction between the T cell and macrophage,” Turner said.

Conventional wisdom suggests the strong innate response is good for old mice and people, but the question remains: Could the acquired response be stronger if the innate response didn’t kick in first? Turner and Szomolay are currently developing a new math model that will eliminate the innate response in an old mouse to observe the infection outcome under those circumstances.

This work is supported by the National Science Foundation and the National Institute on Aging. Avner Friedman, director of Ohio State’s Mathematical Biosciences Institute, is a co-author of the study. The research appears in a recent issue of the journal Experimental Gerontology.

Adapted from materials provided by Ohio State University.

T cells, TB, immune system, infection, macrophages, tuberculosis, white blood cells     0 Comments

Immune system

Aug 25

The immune system is the system of specialized cells and organs that protect an organism from outside biological influences.

(Though in a broad sense, almost every organ has a protective function - for example, the tight seal of the skin or the acidic environment of the stomach.) When the immune system is functioning properly, it protects the body against bacteria and viral infections, destroying cancer cells and foreign substances.

If the immune system weakens, its ability to defend the body also weakens, allowing pathogens, including viruses that cause common colds and flu, to grow and flourish in the body.

The immune system also performs surveillance of tumor cells, and immune suppression has been reported to increase the risk of certain types of cancer..

For more information about the topic Immune system, read the full article at Wikipedia.org, or see the following related articles:

White blood cell — White blood cells (also called leukocytes or immune cells) are cells which form a component of the blood. They help to defend the body against …  > read more

T cell — T cells are a subset of lymphocytes that play a large role in the immune response. The abbreviation “T” stands for thymus, the organ in which their …  > read more

Antiviral drug — Antiviral drugs are a class of medication used specifically for treating viral infections. Like antibiotics, specific antivirals are used for …  > read more

Note: This page refers to an article that is licensed under the GNU Free Documentation License. It uses material from the article Immune system at Wikipedia.org. See the Wikipedia copyright page for more details.

NK cells, T cells, immune system, infection, inflammation, low white blood count, macrophages, natural killer cells     0 Comments

Reishi Mushroom Extract: An Important Supplement For Immune Support And Other Health Conditions

May 12

Written by Dr. James Meschino, D.C., M.S.,
– Research and Clinical Director, RenaiSanté Institute of Integrative Medicine –

Recent And Historical Use Of Reishi Mushroom Extract
Reishi mushroom (Ganoderma lucidum) is called “the mushroom of immortality” in China and has been used in Oriental Medicine for over 2,000 years. (1,2) In recent years its active ingredients have been the subject of intensive research regarding their apparent ability to help prevent or treat certain types of cancer, aid in the treatment of liver disease, HIV infection, acute or recurrent herpetic infections, high blood pressure, chronic bronchitis, allergies and asthma, and favorably modulate immune function. (3) The reishi mushroom grows wild on decaying logs and tree stumps in the coastal provinces of China. The fruiting body of the mushroom is used medicinally. (4)

Active Constituents: Reishi mushrooms contain a number of active agents that are known to modulate function of the immune system in humans. The primary agents include:

  1. Specific Polysaccharides - which occur in the form of Beta-D-glucans bound to amino acids. These agents are known to possess immune-modulating and anti-cancer properties. (3)
  2. Triterpene compounds - known as ganoderic acids, which have been shown to lower blood pressure, reduce platelet stickiness and may decrease LDL-cholesterol. (5)
  3. Other major active constituents - including sterols, coumarin and mannitol. (5)

Clinical Application and Mechanism of Action

  1. Anti-Cancer Agent: Cancer studies in animals have shown a 50% tumor regression rate with reishi mushroom extract treatment (e.g., connective tissue cancer model in mice). (6) Reishi mushroom extract is used by some cancer surgeons in Japan to treat cancer patients and significant anti-tumor and immunostimulation effects have been noted in many of these cases. (7) Polysaccharides from reishi mushrooms and from other types of folk-medicinal fungi are patented in Japan for use as immunomodulators in the treatment of cancer. They are combined with chemo- and radiotherapy and have demonstrated an ability to reduce side effects, increase the efficacy of treatments, and are used to accelerate recovery from disease. (8,9)
    Studies from China have shown that reishi mushroom extract potentiates the tumoricidal capacity of macrophages and T-cells. (10,11) Reishi mushroom extract is known to have other immune modulating effects and antioxidant properties as well. (12,13,14,15,16)
  2. Immune System Enhancement: (Bronchitis, Asthma, Allergies, Herpetic Conditions and HIV Infection) As noted above, reishi mushroom extract modulates many components of the immune system, which in part, account for its apparent anti-tumor properties. Chronic bronchitis in the elderly has been shown to respond favorably to treatment using a concentrated reishi mushroom product in a trial involving 2,000 cases in China. This study demonstrated a better than 60% success rate. After several months of treatment there was a noted rise in the levels of immunoglobulin A in the sputum. (10
    The combination of astragalus and reishi mushroom extract represents an effective means of daily immune support and a therapeutic intervention for a large number of immune compromised states (e.g.,chronic fatigue, chronic bronchitis, herpes I and II recurrent infections, post-herpetic neuralgia, recurrent apthous ulcers or canker sores, the common cold, HIV infection, etc.) and for patients undergoing chemo-or radiation therapy.
  3. Cardiovascular Health: (High Blood Pressure and Reduced Platelet Aggregation) Two human controlled studies revealed that reishi mushroom extract can reduce high blood pressure to a significant degree (systolic and diastolic), even in patients who had previously failed to respond to established anti-hypertensive medications. (30,31) Animal studies reveal that reishi mushroom extract reduces blood pressure through a central inhibition of sympathetic nerve activity, although it does not slow heart rate or induce a sedative effect in general. (32
  4. Liver Protective Effects: (Hepatoprotective Properties) Reishi is prescribed in China for the treatment of chronic and acute hepatitis. (36) Various ganoderic acids in reishi mushrooms have strong antihepatotoxic properties, (37) which under experimental conditions have been shown to protect liver cells from chemically-induced injury, including protection from the highly toxic and lethal substance, carbon tetrachloride. (38,39)

HIV, T cells, allergies, anti-cancer agents, asthma, astragalus, chronic fatigue, herpes, high blood pressure, immune system, infection, macrophages, mouth sores, polysaccharides, reishi mushroom     0 Comments