How does the immune system work with the cardiovascular system

The human body contains trillions of cells, 78 different organs and more than 60,000 miles of blood vessels if you stretched them end-to-end. Incredibly, all of these cells, vessels and organs work together to keep you alive.

Each organ belongs to one of ten human body systems. These body systems are interconnected and dependent upon one another to function. Your heart does not beat unless your brain and nervous system tell it to do so. Your skeletal system relies on the nutrients it gains from your digestive system to build strong, healthy bones.

There are 10 body systems:

1. Circulatory
2. Respiratory
3. Nervous
4. Muscular
5. Skeletal
6. Digestive
7. Endocrine (hormones)
8. Lymphatic, or immune system
9. Reproductive
10. Integumentary (skin, hair)

A body system is a group of parts that work together to serve a common purpose. Your cardiovascular system works to circulate your blood while your respiratory system introduces oxygen into your body.

Each Body System Works with the Others

Each individual body system works in conjunction with other body systems. The circulatory system is a good example of how body systems interact with each other. Your heart pumps blood through a complex network of blood vessels. When your blood circulates through your digestive system, for example, it picks up nutrients your body absorbed from your last meal. Your blood also carries oxygen inhaled by the lungs. Your circulatory system delivers oxygen and nutrients to the other cells of your body then picks up any waste products created by these cells, including carbon dioxide, and delivers these waste products to the kidneys and lungs for disposal. Meanwhile, the circulatory system carries hormones from the endocrine system, and the immune system’s white blood cells that fight off infection.

Each of your body systems relies on the others to work well. Your respiratory system relies on your circulatory system to deliver the oxygen it gathers, while the muscles of your heart cannot function without the oxygen they receive from your lungs. The bones of your skull and spine protect your brain and spinal cord, but your brain regulates the position of your bones by controlling your muscles. The circulatory system provides your brain with a constant supply of oxygen-rich blood while your brain regulates your heart rate and blood pressure.

Even seemingly unrelated body systems are connected. Your skeletal system relies on your urinary system to remove waste produced by bone cells; in return, the bones of your skeleton create structure that protects your bladder and other urinary system organs. Your circulatory system delivers oxygen-rich blood to your bones. Meanwhile, your bones are busy making new blood cells.

Working together, these systems maintain internal stability and balance, otherwise known as homeostasis. Disease in one body system can disrupt homeostasis and cause trouble in other body systems. If you become ill with the AIDS virus that affects your immune system, for example, you may develop pneumonia in your respiratory system, a yeast infection in your reproductive system, Candida that affects your esophagus in your digestive system or the skin cancer known as Kaposi’s sarcoma.

For more information on the connection between body systems, talk to your health professional at Revere Health. We offer family practice and 39 medical specialties to help all ten of your body systems work together. 

Sources:
Organs of the Body
Cleveland Clinic
AIDS.org

The Body’s First Line of Defence
Fluid Systems of The Body
How The Immune System Works
Immune System Process 

The purpose of this section is to review the organs, cell types and interactions between cells of the immune system as a commentary on their importance and interdependence. Such an understanding may help comprehend the root of immune deficiencies and how the immune system is critical in the case of specific diseases.

The Body’s First Line of Defense

The immune system is a complex of organs–highly specialized cells and even a circulatory system separate from blood vessels–all of which work together to clear infection from the body. The organs of the immune system, positioned throughout the body, are called lymphoid organs. The word “lymph” in Greek means a pure, clear stream–an appropriate description considering its appearance and purpose.

The immune system is composed of many interdependent cell types that collectively protect the body from bacterial, parasitic, fungal, viral infections and from the growth of tumor cells. Many of these cell types have specialized functions. The cells of the immune system can engulf bacteria, kill parasites or tumor cells, or kill viral-infected cells. Parts of the immune system are antigen-specific (they recognize and act against particular antigens), systemic (not confined to the initial infection site, but work throughout the body), and have memory (recognize and mount an even stronger attack to the same antigen the next time).

Fluid Systems of the Body

There are two main fluid systems in the body: blood and lymph. The blood and lymph systems are intertwined throughout the body and they are responsible for transporting the agents of the immune system.

(1) The Blood System
The 5 liters of blood of a 70 kg (154 lb) person constitute about 7% of the body’s total weight. The blood flows from the heart into arteries, then to capillaries, and returns to the heart through veins.

Blood is composed of 52–62% liquid plasma and 38–48% cells. The plasma is mostly water (91.5%) and acts as a solvent for transporting other materials (7% protein and 1.5% other “stuff”).

All blood cells are manufactured by stem cells, which live mainly in the bone marrow. The stem cells produce hemocytoblasts that differentiate into the precursors for three types of blood cells:

a) erythrocytes (red blood cells),
b) leukocytes (white blood cells ) (including the sub-category of Lymphocytes), and
c) thrombocytes (platelets).

(2) The Lymph System

Lymph is an alkaline (pH > 7.0) transparent fluid containing white blood cells, chiefly lymphocytes. Lymph bathes the tissues of the body, and the lymphatic vessels collect and move it eventually back into the blood circulation. There are no Red Blood Cells in lymph and it has a lower protein content than blood.

The human lymphoid system has the following:

– Primary organs: bone marrow (in the hollow center of bones) and the thymus gland (located behind the breastbone above the heart), and -secondary organs at or near possible portals of entry for pathogens: adenoids, tonsils, spleen (located at the upper left of the abdomen), lymph nodes (along the lymphatic vessels with concentrations in the neck, armpits, abdomen, and groin), Peyer’s patches (within the intestines), and the appendix.

– Lymphatic vessels and lymph nodes are the parts of the special circulatory system that carries lymph, Lymph nodes dot the network of lymphatic vessels and provide meeting grounds for the immune system cells that defend against invaders. The spleen, at the upper left of the abdomen, is also a staging ground and a place where immune system cells confront foreign microbes.

Both immune cells and foreign molecules enter the lymph nodes via blood vessels or lymphatic vessels. All immune cells exit the lymphatic system and eventually return to the bloodstream. Once in the bloodstream, lymphocytes are transported to tissues throughout the body, where they act as sentries on the lookout for foreign antigens.

How the Immune System Works

Cells that will grow into the many types of more specialized cells that circulate throughout the immune system are produced in the bone marrow. This nutrient-rich, spongy tissue is found in the center shafts of certain long, flat bones of the body, such as the bones of the pelvis. The cells most relevant for understanding vaccines are the lymphocytes, numbering close to one trillion.

Lymphocytes come in two major types: B Cells and T Cells. The peripheral blood contains 20–50% of circulating lymphocytes; the rest move in the lymph system. Roughly 80% of them are T cells, 15% B Cells and the remainder are null or undifferentiated cells. lymphocytes constitute 20–40% of the body’s WBCs. Their total mass is about the same as that of the brain or liver. B Cells grow to maturity in the bone marrow, and T cells mature in the thymus, high in the chest behind the breastbone.

(1) B Cells
B Cells produce antibodies that circulate in the blood and lymph streams and attach to foreign antigens to mark them for destruction by other immune cells. B Cells are part of what is known as antibody-mediated or humoral immunity, so called because the antibodies circulate in blood and lymph, which the ancient Greeks called, the body’s “humors.”

B Cells become plasma cells, which produce antibodies when a foreign antigen triggers the immune response.

(2) T cells
T cells have two major roles in immune defense. Regulatory T-Cell are essential to orchestrate, regulate and coordinate the overall immune response. T lymphocytes are responsible for cell-mediated immunity (or cellular immunity).

Helper T cells, for example, also known as CD4 positive T cells (CD4+ T cells), alert B Cells to start making antibodies; they also can activate other T cells and immune system scavenger cells called macrophages and influence which type of antibody is produced.

Certain T cells, called CD8 positive T cells (CD8+ T cells), can become killer cells that attack and destroy infected cells. The killer T cells are also called cytotoxic T cells or CTLs (cytotoxic lymphocytes).

Natural Killer Cells — Natural killer cells, often referred to as NK cells, are similar to the killer T cell subset (CD8+ T cells). They function to directly kill certain tumors such as melanomas, lymphomas and viral-infected cells. NK cells, unlike the CD8+ (killer) T cells, kill their targets without a prior “conference” in the lymphoid organs. However, NK cells that have been activated by secretions from CD4+ T cells will kill their tumor or viral-infected targets more effectively.

Antibodies — Antibodies produced by cells of the immune system recognize foreign antigens and mark them for destruction.

The antibodies that B Cells produce are basic templates with a special region that is highly specific to target a given antigen. Different antibodies are destined for different purposes. Some coat the foreign invaders to make them attractive to the circulating scavenger cells, phagocytes, that will engulf an unwelcome microbe.

When some antibodies combine with antigens, they activate a cascade of nine proteins, known as complement, that have been circulating in inactive form in the blood. Complement forms a partnership with antibodies, once they have reacted with antigen, to help destroy foreign invaders and remove them from the body. Still other types of antibodies block viruses from entering cells.

Immune System Process

Activation of helper T cells
After it engulfs and processes an antigen, the macrophage displays the antigen fragments combined with a protein on the macrophage cell surface. The antigen-protein combination attracts a helper T cell, and promotes its activation.

Activation of cytotoxic T cells
After a macrophage engulfs and processes an antigen, the macrophage displays the antigen fragments combined with a protein on the macrophage cell surface. A receptor on a circulating, resting cytotoxic T cell recognizes the antigen-protein complex and binds to it. The binding process and a helper T cell activate the cytotoxic T cell so that it can attack and destroy the diseased cell.

Activation of B Cells to make antibody
A B-cell uses one of its receptors to bind to its matching antigen, which the B cell engulfs and processes. The B cell then displays a piece of the antigen, bound to a protein, on the cell surface. This whole complex then binds to an activated helper T cell. This binding process stimulates the transformation of the B cell into an antibody-secreting plasma cell.

Often, these cells depend on the T helper subset for activation signals in the form of secretions formally known as cytokines, lymphokines, or more specifically interleukins.