Lymphatic, Immune, and GI Flashcards

Question 1

Q

What are the three major functions of the lymphatic system?

Answer

A

Maintain body fluid level, return fluid from the tissues back to the heart

Helps large molecules like proteins, hormones, and lipids enter the blood

Immune protection and surveillance

Question 2

Q

What is the lymphatic system composed of?

Answer

A

Lymph, lymphocytes, lymphatic vessels and plexuses, lymph nodes, and other lymphoid organs.

Question 3

Q

What is the definition of a lymphoid organ? What are examples of lymphoid organs?

Answer

A

Lymphoid organs are the part of the lymphatic system that are directly involved in the immune system because they house or produce lymphocytes and other white blood cells.

Examples of lymphoid organs are the thymus, bone marrow, spleen, lymph nodes, and tonsils.

Question 4

Q

Which lymphoid organs produce lymphocytes?

Answer

A

The thymus and bone marrow

Question 5

Q

Which lymphoid organs house lymphocytes and other white blood cells?

Answer

A

The spleen and tonsils

Question 6

Q

What is lymph and where is it transported?

Answer

A

Lymph is a clear - or slightly yellow - fluid that is transported through tubes like blood vessels, called lymphatic vessels. Lymph fluid enters the extracellular space at capillary beds in the tissues during gas and nutrient exchange.

Question 7

Q

What is the path of the lymphatic vessels to pick up and transport lymph?

Answer

A

Lymphatic capillaries > lymphatic vessels > lymph nodes > lymphatic trunks > lymphatic ducts

Question 8

Q

What are the two lymphatic ducts in the body called?

Answer

A

The right lymphatic duct and the thoracic duct

Question 9

Q

Where does the right lymphatic duct collect lymph from and where does it drain lymph to?

Answer

A

The right lymphatic duct collects the lymph from the right side of the head and neck, the right side of the chest, and the right upper limb

This duct drains its lymph into the right venous angle, the lymph then mixes with blood and drains into the superior vena cava, the lymph then enters the right atrium of the heart

Question 10

Q

Where does the thoracic duct collect lymph from and where does it drain lymph to?

Answer

A

The thoracic duct collects lymph from the rest of the body not collected by the right lymphatic duct. This includes the left side of the head and neck, the left side of the chest, the left upper limb, the abdomen and both lower limbs.

The thoracic duct travels through the thoracic cavity and drains into the left venous angle. The lymph then mixes with blood and drains into the superior vena cava. The lymph then enters the right atrium of the heart

Question 11

Q

What are the three major functions of the lymphatic system?

Answer

A

Maintain body fluid level, return fluid from the tissues back to the heart

Helps large molecules like proteins, hormones, and lipids enter the blood

Immune protection and surveillance

Question 12

Q

What is lymph?

Answer

A

Fluid water and protein in lymph vessels. It is made up of fluid water and protein that seeps out of the capillaries and into the interstitial fluid during gas and nutrient exchange

Question 13

Q

Is the lymphatic system a closed loop?

Answer

A

No, fluid and proteins make their way into the microscopic lymphatic capillaries, and all the collected lymph is dumped into the veins. Lymph flows one-way only, from the tissues to the heart

Question 14

Q

Is the circulatory system a closed loop?

Answer

A

Yes, the blood leaves the heart and re-enters the heart through a tightly controlled circuit

Question 15

Q

Are lymphatic capillaries permeable? Why or why not?

Answer

A

Yes, they are extremely permeable because their walls are made of endothelial cells that only loosely overlap, forming one-way mini-valves. These endothelial cells are anchored to structures in the interstitial space by collagen filaments, which allow the lymphatic capillaries to remain flexible but retain their overall shape

Question 16

Q

What drives fluid to flow into lymphatic capillaries? Can fluid flow out of lymphatic capillaries and back into the interstitial space? Why or why not?

Answer

A

When the pressure in the interstitial space is greater than the pressure in the lymphatic capillary, the endothelial mini-valves open, allowing fluid to enter.

Fluid cannot flow back out of the lymphatic capillaries into the interstitial space. When the pressure in the interstitial space is less than the pressure in the lymphatic capillary, the endothelial mini-valves are pushed shut, keeping the lymph inside

Question 17

Q

How does lymph move through the lymphatic system from lymph vessels to trunks?

Answer

A

There’s no central pump pushing the lymph through the lymphatic system. The lymphatic pump is a result of spontaneous contraction of smooth muscle in lymphatic vessels in response to intrinsic and extrinsic factors including increased lymphatic fluid pressure, pulsing of nearby arteries, and the squeezing of skeletal muscles

Question 18

Q

What prevents lymph from flowing backward in the lymphatic vessels?

Answer

A

The lymphatic vessels have valves just like the veins

Question 19

Q

What are the two lymphatic ducts in the body called?

Answer

A

The right lymphatic duct and the thoracic duct

Question 20

Q

Where does the right lymphatic duct collect lymph from?

Answer

A

This duct collects the lymph from the right side of the head and neck, the right side of the chest, and the right upper limb

Question 21

Q

Where does the right lymphatic duct drain lymph?

Answer

A

This duct drains its lymph into the right venous angle, the lymph then mixes with blood and drains into the superior vena cava, the lymph then enters the right atrium of the heart

Question 22

Q

Where does the thoracic duct collect lymph from?

Answer

A

This duct collects lymph from the rest of the body not collected by the right lymphatic duct. This includes the left side of the head and neck, the left side of the chest, the left upper limb, the abdomen, and both lower limbs

Question 23

Q

Where does the thoracic duct drain lymph?

Answer

A

The thoracic duct travels through the thoracic cavity and drains into the left venous angle. The lymph then mixes with blood and drains into the superior vena cava the lymph then enters the right atrium of the heart

Question 24

Q

What are some key advantages of the lymphatic system over the circulatory system?

Answer

A

It can pick up larger molecules, like hormones, that are too large to get into the capillaries and get them into the bloodstream

The lymphatic system can also help get nutrients to the tissues, specifically chylomicrons, these balls of fat are too large to move across capillaries but can travel in lymphatic vessels and into the thoracic duct then into the venous blood.

Question 25

Q

What is the lymphatic system’s role in immune function?

Answer

A

Lymphoid organs remove foreign material from the lymph to keep it from entering the bloodstream and act as lookout points for the body’s immune defenses.

Question 26

Q

What is the definition of a lymphoid organ? What are examples of lymphoid organs?

Answer

A

Lymphoid organs are the part of the lymphatic system that are directly involved in the immune system because they house or produce lymphocytes and other white blood cells.

Examples of lymphoid organs are the thymus, bone marrow, spleen,lymph nodes, and tonsils

Question 27

Q

How do lymph nodes assist with immune function?

Answer

A

When an infection gets into the tissue, it can slip into a lymphatic capillary and move into a lymphatic vessel which drains into a nearby lymph node where any pathogen or piece of pathogen is detected by a dendritic cell, B cell, or T cell

Question 28

Q

What are B cells and T cells?

Answer

A

Types of lymphocytes in the lymph nodes that help with the immune response

Dendritic cells sample the lymph and present antigens that they come across to the B cells which produce antibodies that flow into the lymph exiting the lymph node.

T cells are another type of lymphocyte that move between the lymph nodes, lymph, and blood on the lookout for pathogens and infected or abnormal cells that have been tagged by antibodies

Question 29

Q

Where is the spleen located and are the functions of its two main divisions?

Answer

A

It is a lymphoid organ that sits on the left side of the body below the diaphragm and on top of the stomach.

The spleen has both white pulp and red pulp. The white pulp assists with immune function by generating B cells and the red pulp is where old and defective blood cells are destroyed, and their parts are either broken down or recycled

Question 30

Q

How does the spleen assist with immune function?

Answer

A

The white pulp of the spleen is where antibody-coated bacteria are filtered out of circulation and antibodies are generated by B cells

Question 31

Q

Where is the thymus located and when is it most active throughout the lifespan?

Answer

A

The thymus is a lymphoid organ in the upper part of the chest that is most active in the neonatal period and pre-adolescent years, and then slowly atrophies and gets replaced by fat after puberty.

Question 32

Q

How does the thymus assist with immune function?

Answer

A

The thymus is involved in the development of T cells - making sure that any T cells that react to self-antigens, antigens that are normally found in the body, are promptly destroyed.

Question 33

Q

How do the tonsils assist with immune function?

Answer

A

The tonsils form a ring of lymphoid tissue around the throat that trap pathogens from ingested food and inhaled air

Question 34

Q

What is the immune system made of and what is its overall function?

Answer

A

The immune system is made up of organs, tissues, cells, and molecules that all work together to generate an immune response that protects us from microorganisms, removes toxins, and destroys tumor cells

Question 35

Q

What are the two main types of immune responses?

Answer

A

The innate immune response and the adaptive immune response

Question 36

Q

How does the innate immune response function in the immune system?

Answer

A

The innate immune response includes cells that are non-specific, meaning that although they distinguish an invader from a human cell, they don’t distinguish one invader from another invader.

The innate response is extremely fast but has no memory so will respond to the same pathogen in the exact same way no matter how many times it sees the pathogen

Question 37

Q

Are chemical barriers like lysosomes in tears, low pH in the stomach, and physical barriers like epithelium in the skin and gut, and airway cilia part o the innate immune response or adaptive immune response?

Answer

A

The innate immune response

Question 38

Q

How does the adaptive immune response function in the immune system?

Answer

A

The adaptive immune response is highly specific for each invader. The cells of the adaptive immune response have receptors that differentiate one pathogen from another by their unique parts - called antigens.

The adaptive immune response is specific but slow. The adaptive response relies on cells being primed or activated, so they can fully differentiate into the right kind of fighter to kill that pathogen, and that can take a few weeks

Question 39

Q

Is adaptive immunity diverse?

Answer

A

Yes, adaptive immunity is diverse, meaning it can recognize almost an infinite number of specific antigens and mount a specific response against each of them

Question 40

Q

What is immunologic memory and clonal expansion?

Answer

A

Cells that are activated in the adaptive immune response undergo clonal expansion which means that they massively proliferate. Each time the adaptive cells see that same pathogen, they massively proliferate again, resulting in a stronger and faster response each time that pathogen comes around

Question 41

Q

What happens to clonally expanded cells activated in the adaptive immune response after the pathogen is destroyed?

Answer

A

Once the pathogen is destroyed, most of the clonally expanded cells die off but some of the clonally expanded cells live on as memory cells and they’re ready to expand if the pathogen ever resurfaces

Question 42

Q

What physiologic structures are the soldiers of the immune system?

Answer

A

The white blood cells or leukocytes

Question 43

Q

What is hematopoiesis and where does it mainly take place?

Answer

A

Hematopoiesis is the process of forming white blood cells, as well as red blood cells, and platelets and it primarily takes place in the bone marrow

Question 44

Q

What are the two most common types of white blood cells? What are the other types?

Answer

A

Neutrophils are the most common, followed by lymphocytes.

Other types of WBCs include eosinophils, basophils, and monocytes

Question 45

Q

How do neutrophils destroy pathogens?

Answer

A

Through phagocytosis, where they get near a pathogen and reach around it with their cytoplasm to “swallow” it whole so that it ends up in a phagosome. Once inside, they use their cytoplasmic granules or an oxidative burst to eliminate the ingested pathogen

Question 46

Q

What is the role of eosinophils, basophils, and mast cells in the immune response?

Answer

A

They are less common than neutrophils and they contain histamine and other pro inflammatory molecules. They are not phagocytic and are involved in allergic responses. Eosinophils are also known for fighting off parasites. Eosinophils and basophils are WBCs and mast cells live in the tissues

Question 47

Q

What is the role of monocytes, macrophages, and dendritic cells in the immune response?

Answer

A

They are also phagocytic cells - they gobble up pathogens, present antigens, and release cytokines - which are tiny molecules that attract other immune cells to the area.Dendritic cells are antigen-presenting cells. Dendritic cells are usually found in sites that are in contact with most external antigens - like the skin epithelium, or the gastrointestinal mucosa

Question 48

Q

Which are found in the blood, monocytes or macrophages?

Answer

A

Monocytes, some monocytes migrate into tissues and differentiate into macrophages, which remain in tissues and aren’t found in the blood

Question 49

Q

What do dendritic cells do after phagocytosing a pathogen?

Answer

A

Destroy the pathogen and break up its proteins into short amino acid chains. Dendritic cells will then move through the lymph to the nearest lymph node, and they’ll perform an antigen presentation, which is where they present those amino acid chains - which are antigens - to Tcells

Question 50

Q

What connects the innate and adaptive immune responses?

Answer

A

Antigen presentation is what connects the innate and adaptive immune responses. Antigen presentation is something that can be done by dendritic cells, macrophages, and monocytes

Question 51

Q

Which cells are referred to as antigen-presenting cells?

Answer

A

Dendritic cells, macrophages, and monocytes

Question 52

Q

Which of the antigen-presenting cells are best at antigen presenting and why?

Answer

A

Dendritic cells are the best at antigen presentation to T cells because they are the only cells that live where pathogens enter (through epithelia like the skin, gut, and airways) and they are the only cells that can traffic from these tissues to lymph nodes, where Tcells circulate

Question 53

Q

What is priming specific to the immune responses?

Answer

A

Only T cells with a receptor that can bind to the specific shape of the antigen will be activated

Question 54

Q

How do T cells recognize an antigen it can bind to?

Answer

A

T cells can only see their antigen if it is presented on a Major Histocompatibility complex molecule (MHC). The antigen-presenting cell will load the antigen on an MHC molecule and display it to T cells, and when the right T cell comes along it binds

Question 55

Q

What blood cells are lymphocytes? Which are involved in the innate response and which in the adaptive response?

Answer

A

B cells, T cells, and natural killer cells

B and T cells are part of the adaptive immune response and naturalkiller cells are part of the innate immune response

Question 56

Q

Where are B cells developed?

Answer

A

Bone marrow

Question 57

Q

Where are T cells developed?

Answer

A

Start in bone marrow then travel to the thymus where they develop into T cells

Question 58

Q

Where are natural killer cells developed?

Answer

A

Bone marrow

Question 59

Q

Can lymphocytes travel in blood, tissue, or both?

Question 60

Q

What is the role of natural killer cells in the immune response?

Answer

A

Natural killer cells are large lymphocytes with granules, they target cells infected with intracellular organisms, like viruses, as well as cells that pose a threat like cancer cells.

Natural killer cells kill their target cells by releasing cytotoxic granules and are involved in the innate immune response.

Question 61

Q

How are B cells and T cells alike and different in the immune response?

Answer

A

B cells and T cells both have a receptor on their surface that allows them to only bind to an antigen that has a very specific shape.

B cells do not need antigens to be presented to them on an MHC molecule like T cells. They can simply bind to an antigen directly

Question 62

Q

How do B cells and T cells work together in the adaptive immune response?

Answer

A

When a B cell binds to a protein antigen that’s on the surface of a pathogen, it is capable of internalizing that antigen, degrading it, and presenting it to T cells - so technically, they’re also antigen-presenting cells as well. Like other antigen-presenting cells, the B cell loads the antigen onto an MHC molecule called MHC II and displays it to T cells.

When a T cell gets activated, it helps the B cell mature into a plasma cell, and a plasma cell can secrete lots and lots of antibodies. Typically, it takes a few weeks for antibody levels to peak

Question 63

Q

What are antibodies?

Answer

A

Antibodies, or immunoglobulins, have the exact same antigen specificity as the B cell they come from

Antibodies are just the B cell receptors in a secreted form, so they can circulate in the plasma, which is the non-cellular part of blood -attaching to pathogens and tagging them for destruction. Because antibodies aren’t bound to cells and float freely in the blood, this is considered humoral immunity

Question 64

Q

Which cell type is involved in humoral immunity?

Answer

A

B cell antibodies which aren’t bound to cells and float freely in the blood

Answer 64

A

T cells, they are antigen specific, but they cannot secrete their antigen receptor. A naive T cell can be activated or primed to allow it to turn into a mature T cell by any of the antigen-presenting cells, but most often it’s done by a dendritic cell.

Answer 65

A

CD4 T cells and CD8 T cells - where “CD” stands for cluster of differentiation

Answer 66

A

CD4 T cells are called helper T cells, and they secrete cytokines that help coordinate the efforts of macrophages and B cells.

Answer 67

A

CD8 T cells are called cytotoxic T cells because they kill target cells, like how natural killer cells do it with one major difference. CD8+ Tcells only kill cells that present a specific antigen on an MHC I molecule, whereas natural killer cells aren’t nearly as specific in who they kill

Answer 68

A

Tiny proteins that are secreted by both immune and non-immune cells to communicate with one another.

Answer 69

A

They bind to receptors and trigger a response in the receiving cell.

They promote activation, proliferation, and differentiation of immune cells, but they can also increase the body temperature, causing a fever

Answer 70

A

Autocrine means the cell producing the cytokine is also the cell responding to the cytokine.

Paracrine means that the cytokine is produced by one cell and that it affects cells in the near vicinity.

Endocrine, which is when the cytokine affects a cell that’s far away, perhaps in a different organ

Answer 71

A

Mostly autocrine and paracrine but occasionally endocrine

Answer 72

A

Interleukins, Tumor Necrosis Factors, Interferons, Transforming Growth Factors, and Colony Stimulating Factors

Answer 73

A

They are the most varied group of cytokines and are released and act on both leukocytes as well as non-leukocytes.

Answer 74

A

They elicit inflammation and the inflammatory cells. They have a wide variety of biological effects in the inflammatory response, including activating endothelial cells to up regulate the expression of adhesion molecules and increasing vascular permeability

Answer 75

A

They interfere with processes like viral replication

Answer 76

A

They suppress the proliferation and differentiation of various cells to slow down or stop the overall immune response

Answer 77

A

These cytokines bind to surface receptors on hematopoietic stem cells, causing them to proliferate and differentiate

Answer 78

A

The innate immune response and the adaptive immune response

Answer 79

A

The innate response will respond to the same pathogen in the exact same way no matter how many times it sees the pathogen. It is faster than the adaptive response

The adaptive response is highly specific for each invader. It is slower than the innate response

Answer 80

A

Chemical barriers- lysozymes in the tears and a low pH in the stomach

Physical barriers- epithelium in the skin and gut, and the cilia lining the airways

Answer 81

A

These immune cells have receptors called pattern recognition receptors (PRRs) that recognize the molecules that a pathogen has on its surface called pathogen associated molecular patterns (PAMPs)

Answer 82

A

The lymphocytes- B cells and T cells

Answer 83

A

It gets secreted as an antibody with the exact same antigen specificity.These antibody classes are immunoglobulins: IgM, IgD, IgG, IgA, andIgE

Answer 84

A

Skin and its accessory structures, like oil and sweat glands

Answer 85

A

It protects the body from infections, helps regulate body temperature, and contains nerve receptors that detect pain (nociception), sensation, and pressure.

Answer 86

A

The epidermis is the most superficial layer and it’s responsible for protection from pathogens, the environment, and for vitamin D production

The dermis lies below the epidermis and controls temperature regulation, helps with sensation, and gives the skin its color.

The hypodermis lies below the dermis and provides a point of attachment for the skin to the deeper muscles

Answer 87

A

It contains nerves and blood vessels

Answer 88

A

Hypodermis layer is made of fat and connective tissue that anchors the skin to the underlying muscle

Answer 89

A

They are flat pancake-shaped cells that are named for the keratin protein that they’re filled with

Answer 90

A

It is a fibrous protein that allows keratinocytes to protect themselves from getting destroyed

Answer 91

A

They help to prevent water from easily seeping into and out ofthe body

Answer 92

A

They are in the stratum basale layer, and they secrete a protein pigment, or coloring substance, called melanin

Answer 93

A

Melanin is a broad term that constitutes several types of melanin found in people of differing skin color. These subtypes of melanin range in color from black to reddish yellow and their relative quantity defines a person’s skin color

Answer 94

A

When keratinocytes are exposed to the sun, they send a chemical signal to the melanocytes, which stimulates the melanocytes into making more melanin

The melanocytes move the melanin into small sacs called melanosomes, and these get taken up by newly formed keratinocytes.

Melanin then acts as a natural sunscreen, because its structure dissipates, or scatters, UVB light–which if left unchecked can damage the DNA in the skin cells and lead to skin cancer

Answer 95

A

Keratinocytes contain cholesterol precursor molecules that are activated by UVB into Vitamin D

Answer 96

A

The process where the keratinocytes flatten out and die, and in the process, they create the epidermal skin barrier

Answer 97

A

Keratinization leads to the development of the stratum lucidum layer which is 2 to 3 cell layers thick of translucent, dead keratinocytes that have secreted most of their lamellar granules

Answer 98

A

The stratum lucidum is only found in thick skin like on the palms and soles of the feet, because those are the areas that need extra protection

Answer 99

A

The dead keratinocytes in the stratum corneum layer secrete natural antibiotics called defensins which poke holes in bacteria.

Answer 100

A

The dermis lies below the stratum basale of the epidermis and it’s much thicker than the epidermis.

Answer 101

A

The dermis is divided into two layers - a thin papillary layer below the stratum basale and a deeper reticular layer

Answer 102

A

The papillary layer contains fibroblasts which produce a connective tissue protein called collagen and macrophages which capture pathogens that make it past the epidermis

Answer 103

A

The fibroblasts are arranged in finger-like projections called papillae; each of which contains blood vessels and nerve endings.

Answer 104

A

A disk-shaped nerve ending structure that detects fine touch

Answer 105

A

Dendrites that detect pain (nociception).

Answer 106

A

Like the papillary layer, the reticular layer contains fibroblasts with scattered macrophages

But the collagen in the reticular layer is packed very tightly together, making it excellent tissue support.

Fibroblasts in the reticular layer secrete elastin–which is a stretchy protein that gives skin its flexibility.

The reticular layer also contains the skin’s accessory structures like oil and sweat glands, hair follicles, lymphatic vessels, and nerves - and all of the blood vessels that serve these tissues

Answer 107

A

An onion-shaped nerve ending structure that detects pressure or vibration

Answer 108

A

When body temperature rises, like during a workout, the nervous system makes these blood vessels dilate, and makes the sweat glands secrete sweat.

Dilation of blood vessels brings more blood closer to the skin surface, and that allows heat to get lost to the outside environment.

As sweat coats the skin’s surface, it takes heat to evaporate - so heat is slowly lost from the skin surface with every drop of sweat that evaporates away.

In the opposite situation, when it’s cold outside, blood vessels constrict and that diverts blood flow away from the skin and there’s no sweat -so body heat is conserved.

Answer 109

A

It contains fat cells called adipocytes which help store most of the fat in our body, but also contains fibroblasts, macrophages, blood vessels, nerves, and lymphatics

Answer 110

A

It helps insulate deeper tissues, provides padding to the body, and anchors the skin to the muscle with connective tissue proteins like collagen

Answer 111

A

Mouth, pharynx, esophagus, stomach, small intestine, large intestine, and anal canal

Answer 112

A

Teeth, tongue, salivary glands, liver, gallbladder, and pancreas

Answer 113

A

Ingestion, digestion, absorption, and excretion

Answer 114

A

Salivary amylase

Answer 115

A

A series of coordinated wave-like smooth muscle contractions in the GItract that help squeeze the food bolus in one direction

Answer 116

A

To prevent food from passing from one part of the GI tract to another

Answer 117

A

This is a network of nerves that help coordinate muscle contraction and relaxation. When activated, the myenteric plexus causes smooth muscle relaxation

Answer 118

A

The submucous plexus is responsible for helping to control the size of the blood vessels as well as the secretion of digestive juices

Answer 119

A

The outermost layer of the mucosa is the muscularis mucosa or muscularis interna, it’s a layer of smooth muscle that contracts and helps break down food.

The middle layer is the lamina propria and it contains blood and lymph vessels.

The innermost epithelial layer, absorbs and secretes mucus and digestive enzymes because this is the layer that comes into direct contact with food

Answer 120

A

It is a sphincter at the end of the stomach that closes while eating,keeping food inside for the stomach to churn repeatedly

Answer 121

A

An extra layer of oblique smooth muscle within the muscularis externa of the stomach

Answer 122

A

They are found on the inner lining of the stomach and these glands contain a variety of secretory cells which produce gastric secretions

Answer 123

A

Gastric secretions are made up of hydrochloric acid, which help destroy any pathogens that slip through the food, an enzyme called pepsin, which chops up proteins, mucus which protects the stomach, as well as water, which turns the bolus into a liquid pulp, called chyme

Answer 124

A

The pyloric sphincter opens, allowing the chyme to pass from the stomach into the small intestine.

Answer 125

A

The duodenum, jejunum, and ileum

The small intestine is where most of the digestion and absorption occurs, with the help of the liver’s bile coming from the gallbladder and the pancreatic enzymes.

Answer 126

A

Increase the surface area of the small intestine to absorb nutrients.

Answer 127

A

The liver, gallbladder, and pancreas.

Answer 128

A

The liver is a massive organ that sits under the right dome ofthe diaphragm, and it makes bile which helps to emulsify fats to make them easier to absorb

Answer 129

A

The gallbladder is the thin-walled, green sac next to the liver, it stores and concentrates the bile that’s made by the liver until it needs to secrete it out into the small intestine to help with fat emulsification

Answer 130

A

The pancreas is a long, skinny gland the length of a dollar bill, next to the duodenum. Hormones from the small intestine stimulate the pancreas to secrete digestive enzymes, water, and bicarbonate that travel through the pancreatic ducts and into the duodenum.

Answer 131

A

Fats in the chyme stimulate the hormone-secreting cells of the small intestine to secrete a hormone called cholecystokinin into the blood which goes to the gallbladder and signals it to secrete bile into the small intestine

Answer 132

A

Bile emulsifies the fat, making fat organize into small “micelles”, which are tiny bubbles of mixed lipids and bile acids, rather than clumping together. This makes them easier to absorb

Answer 133

A

Pancreatic lipase takes the triglycerides from the micelles created by fats and bile and breaks them down into fatty acids and glycerol

Answer 134

A

Pancreatic amylase breaks down carbohydrates into shorter oligosaccharides, and proteases, like trypsin, which cleaves proteins down into smaller peptides

Answer 135

A

To prevent the hydrochloric acid from the stomach from damaging the intestinal mucosa, the small intestine secretes the hormone secretin, which stimulates the pancreatic duct cells to secrete water and bicarbonate.

Bicarbonate helps neutralize the acidic chyme and raising the pH in the intestinal lumen also helps digestive enzymes work more effectively

Answer 136

A

A generous amount of bicarbonate is also secreted by glands lying inthe submucosa of the duodenal wall.

Answer 137

A

Fatty acids and glycerol can easily pass through the small intestinal epithelial and into the lymphatics

Answer 138

A

Special enzymes help absorb sugars, on the top surface or brush border of the intestinal cells, called brush border enzymes.

These are maltase, sucrase, and lactase, which break down the short chains of sugars called oligosaccharides into simple sugars, called monosaccharides. These include glucose, fructose, and galactose

Answer 139

A

There are peptidases which break down peptide chains into single amino acids. The epithelial cells can absorb these nutrients into the blood stream, and from there they can go to various tissues around the body

Answer 140

A

Whatever isn’t absorbed, like fiber, continues its journey onward through the ileocecal sphincter and into the large intestine (AKA colon).

Answer 141

A

The large intestine is basically a one-and-a-half meter or five-foot-long loop that frames the small intestine.

It consists of six parts: the cecum, appendix, ascending colon, transverse colon, descending colon, sigmoid colon , and finally, the rectum.

The large intestine absorbs excess water from the chyme, and that helps condense it into dry fecal matter

Answer 142

A

Trillions of bacteria that colonize the large intestine, the bacteria help produce essential B and K vitamins, as well as gases like carbon dioxide, methane, and sulfurous compounds

Answer 143

A

The chyme slowly moves through the large intestine through small waves of peristalsis that take place over hours or even days

The large intestine absorbs excess water from the chyme, and that helps condense it into dry fecal matter and moves to the rectum

Answer 144

A

Signals travel to parasympathetic neurons in the spinal cord, initiating the defecation reflex. These parasympathetic neurons make the rectum contract and the internal anal sphincter relax.

Meanwhile, signals are sent to the brainstem and thalamus, and when these decide the right moment has come, they allow the external anal sphincter to relax and excrete the feces

Answer 145

A

The fundus, body, and antrum

Answer 146

A

The orad region and caudad region

Answer 147

A

Duodenum of the small intestine

Answer 148

A

In the body of the stomach

Answer 149

A

It activates to become pepsin - an enzyme that helps break down proteins

Answer 150

A

Gastrin increases the HCl secretion of the parietal cells, it increases pepsinogen secretion by the chief cells, and it also increases the contraction of the stomach muscles.

Answer 151

A

It regulates gastric secretions of various glands and controls blood flow to the stomach.

Answer 152

A

It contains three layers of smooth muscle that involuntarily contract in waves called peristalsis, which help the stomach mix, digest and empty the food that it has received

Answer 153

A

The caudad region

Answer 154

A

The myenteric plexus

Answer 155

A

The myenteric and submucosal plexuses make up the enteric nervous system

Answer 156

A

It can function without input from the central nervous system and it is connected to the central nervous system, receiving parasympathetic input to increase gastric secretion and motility, and sympathetic input to inhibit those functions

Answer 157

A

When the orad region of the stomach relaxes due to the relaxation of the lower esophageal sphincter

Answer 158

A

It forces chyme in the pylorus to be recycled back to the body of the stomach for more mixing to break food

Answer 159

A

It increases it

Answer 160

A

It decreases it

Answer 161

A

Helps to manage the body’s metabolism, detoxification, and bile production

Answer 162

A

The porta hepatis is the gate to the liver and contains the hepatic artery, hepatic portal vein, and the common hepatic duct

Answer 163

A

The hepatic artery delivers oxygen-rich arterial blood from the heart to the liver

Answer 164

A

The hepatic portal vein delivers nutrient-rich venous blood from the gastrointestinal tract, but also from the spleen and pancreas

Answer 165

A

The common hepatic duct drains bile from the liver into the gallbladder

Answer 166

A

Detoxification, bile synthesis, metabolism of glucose and lipids, synthesis of proteins and lipoproteins, and vitamin and mineral storage

Answer 167

A

As hepatocytes take in oxygen and nutrients and deposit carbon dioxide into the blood, they pick up and detoxify harmful substances like drugs or alcohol

Answer 168

A

Bile synthesis is important for the digestion and absorption of fats and fat-soluble vitamins in the small intestine.

Answer 169

A

They are involved with glucose and lipid metabolism, they help maintain a normal blood glucose level by storing glucose as glycogen and breaking down glycogen into glucose and they break down fatty acids to generate ATP, using beta-oxidation

Answer 170

A

Hepatocytes synthesize proteins like albumin and coagulation factors that are important for clot formation. They also synthesize two types of lipoproteins: very low-density lipoproteins or VLDL and high-density lipoproteins or HDL

Answer 171

A

When blood glucose levels are high, hepatocytes convert glucose into a storage molecule called glycogen using a process called glycogenesis

When glucose levels are low, the hepatocytes break down the glycogen back into glucose in a process called glycogenolysis.

Answer 172

A

Very low-density lipoproteins or VLDL and high-density lipoproteins or HDL

VLDLs help transport triglycerides, fatty acids, and cholesterol to cells that use them as energy or to adipocytes that store them.

HDLs transport cholesterol from the peripheral cells and tissues back to the liver where they’re broken down to generate energy

Answer 173

A

Yes, you can donate up to 90% of your liver and the remaining 10% can grow it back.

Answer 174

A

Hepatocytes convert cholesterol into bile salts which along with water and bilirubin make up bile

Answer 175

A

Into small ducts between the hepatocytes then into bile ducts, hepaticducts, cystic ducts, then into the gallbladder

Answer 176

A

It is stored and becomes more concentrated and is eventually secreted into the small intestine to help with fat absorption

Answer 177

A

It has both endocrine and exocrine functions.

Its endocrine functions are to secrete pancreatic hormones, insulin, and glucagon into the blood to regulate blood sugar levels.

Its exocrine functions are to help neutralize the acidic stomach content and digest food within the intestines

Answer 178

A

It is an enzyme produced by the pancreas which breaks down carbohydrates

Answer 179

A

They are enzymes produced by the pancreas which break down proteins

Answer 180

A

It is an enzyme produced by the pancreas which breaks down lipids

Answer 181

A

Acinar cells of the pancreas produce enzymes that help digest food, they are mainly stimulated by cholecystokinin and acetylcholine.

Ductal cells produce aqueous secretions that help neutralize the acidic stomach contents. They are mainly secreted by secretin

Answer 182

A

No, the concentration of sodium and potassium in pancreatic secretions is relatively constant

Answer 183

A

The concentration of bicarbonate increases when there’s a higher demand for acid neutralization.

Answer 184

A

Bile is a greenish liquid that’s made by the liver and is stored in the gallbladder

Bile helps with digestion, absorption of fats, and excretion of various molecules

Answer 185

A

Bile is mainly made up of bile salts and phospholipids, with cholesterol, and bile pigments called bilirubin, making up only a small percentage

Answer 186

A

No, normally, lipids are insoluble in water, that’s why bile is needed to help emulsify and solubilize them

Answer 187

A

Bile salts can emulsify large lipid globules into smaller droplets to create a greater surface area upon which pancreatic lipase is able to work to emulsify and help make lipids more soluble

Answer 188

A

Bile is first manufactured in the liver by cells called hepatocytes.

Answer 189

A

Bile flows into the left and right hepatic ducts which eventually merge to form the common hepatic duct. The common hepatic duct then leads to the cystic duct which brings the bile to the gallbladder

Answer 190

A

The gallbladder is a small pear-shaped hollow organ located beneath the liver, and this is where bile is stored and becomes more concentrated

Answer 191

A

When chyme enters the duodenum of the small intestine it stimulates cells in the lining of the intestine to secrete the hormone cholecystokinin into the bloodstream, once it reaches the gallbladder it causes the release of bile from the gallbladder, into the common bile duct, then into the duodenum

Answer 192

A

With bilirubin excretion

Answer 193

A

Bilirubin is the pigment that gives bile its color and it’s actually a byproduct of hemoglobin metabolism. Both bile salts and bilirubin can be recycled via enterohepatic circulation where they’re transported from the intestines back to the liver

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