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Example Questions
Example Question #1 : Understanding Other Immune System Components
Which of the following functions is NOT performed by the lymphatic system?
Provides additional oxygen for body tissues
Transports fat digestates and places them into the bloodstream
Returns interstitial fluid to the bloodstream
Elicits an immune response in the presence of an infection
Provides additional oxygen for body tissues
The lymphatic system is responsible for removing excess fluid from the interstitium and returning it to the bloodstream. The fluid will travel through lymph nodes, which monitor for the presence of microbes in the blood. If microbes are present, the lymph nodes will mount an immune response. The lymphatic system also reroutes fat digestates from the small intestine's capillaries and drains them into the veins of the neck. Lymphatic vessels do not assist in the transfer of oxygen to body tissues.
Example Question #1 : Understanding Other Immune System Components
The lymphatic system is involved in all except which of the following processes?
It is a crucial component of the immune system
Transport red blood cells for destruction in the spleen
Transport fats and fat-soluble vitamins that are absorbed via the digestive tract
Maintain blood volume by reducing fluid loss to the extracellular compartment
Transport red blood cells for destruction in the spleen
Red blood cells generally do not leave the circulatory system; thus there are very few opportunities for lymphatic vessels to pick up red blood cells in the extracellular space.
The lymphatic system plays a key role in transporting immune cells, such as lymphocytes, throughout the body. When fats are emulsified and digested in the small intestine, they are transported into the lymph rather than into the blood. When plasma and fluids leak out of capillaries, the lymphatic system is responsible for collecting and returning these fluids to circulation. A fault in this function of the lymphatic system results in edema.
Example Question #32 : Immune System
What is the most likely mechanism a virus could use to evade the immune system that causes periodic outbreaks in an individual over a long period of time?
The virus is actively causing infected cells to secrete factors that suppress the immune system
The virus is continually evolving and manages to vary its antigenic signature so that it can evade detection
The virus manages to attack immune cells needed to control the infection
The virus remains dormant until a stimulus, such as stress or infection with another pathogen, reactivates the virus
The virus remains dormant until a stimulus, such as stress or infection with another pathogen, reactivates the virus
Some viruses evade the immune system using a mechanism known as latency. The virus essentially becomes dormant, usually in cells such as neurons that have few major histocompatibility (MHC) class I molecules. The combination of limited to no active viral replication combined with residence in cells with few MHC lass I molecules allows the virus to evade routine immune monitoring.
When conditions arise, such as fever due to infection caused by another pathogen or emotional stress, the virus can becomes reactivated and can result in an outbreak.
Example Question #222 : Systems Physiology
Which of the following statements is a commonality between T-cell receptors and B-cell receptors?
Both receptors are able to bind to intact antigens
Both receptors consist of both heavy chains and two light chains to form the antigen binding domain
Both receptors have variable regions that form an antigen binding site
Both receptors recognize antigens in conjunction with major histocompatibility complex (MHC) proteins
Both receptors have variable regions that form an antigen binding site
T-cells generally serve to recognize antigens and escort them to B-cells to elicit a response (helper T-cells) or to recognize antibodies bound to infected cells (cytotoxic T-cells). B-cells, in contrast, will directly secrete antibodies against the antigen after binding of the antigen at the membrane.
Both types of cells have receptors that can bind to antigens, allowing for recognition and communication. Other commonalities include the presence of a transmembrane domain and the presence of a variable region, which will allow for specificity in antigen binding.
The similarities are mainly structural, and the receptors have many functional differences. T-cell receptors will only bind fragments of antigens, while B-cell receptors will bind full molecules. Only T-cell receptors will interact with major histocompatibility complexes (MHC). Though the structure of both receptors types is determined by peptide chains, B-cells use heavy and light chains, while T-cells use alpha and beta chains.
Example Question #5 : Understanding Other Immune System Components
The spleen is an organ of the __________.
circulatory system
immune system
digestive system
respiratory system
immune system
The spleen plays a key role in the immune system as one of the blood filtration centers of the body. It is also involved as a lymphatic organ, allowing filtrates from the blood to be distributed to the body via lymph.
Example Question #223 : Systems Physiology
Which cells of the immune system are largely responsible for phagocytosis?
Macrophages
T helper cells
Antibodies
B cells
Macrophages
Macrophages and neutrophils are the major cells of the immune system responsible for phagocytosis. Phagocytosis means ingestion of material. Therefore these cells work as "garbage collectors" within the body. Cells destined for destruction are tagged for phagocytosis by special molecules.
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