Circulatory System Flashcards

1
Q

What are the primary components of blood?

A
  • plasma
  • red blood cells
  • white blood cells
  • platelets

About 45% of total blood volume is due to cellular components, while the remaining 55% comes from plasma.

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2
Q

What is the normal pH of blood?

A

7.4

Normal blood is slightly basic, and even minute deviations can be very harmful. Thus, pH is tightly regulated by mechanisms such as the bicarbonate buffering system.

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3
Q

What is the difference between acidosis and alkalosis?

A
  • Acidosis is an increase in blood acidity, occurring when blood pH drops below 7.35.
  • Alkalosis is an increase in blood basicity, occurring when blood pH rises above 7.45.
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4
Q

If a person were to hyperventilate continuously, would they eventually experience acidosis or alkalosis?

A

alkalosis

Hyperventilation, or quickened breathing, results in an increased loss of CO2. The reaction proceeds according to this equilibrium:

H2O + CO2 ⇔ H2CO3 ⇔ H+ + HCO3-

When CO2 is excreted, the equilibrium shifts to the left to regenerate it. This requires protons to combine with bicarbonate ions, decreasing the plasma H+ concentration. Lowered H+, or decreased acidity, means that pH will rise.

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5
Q

Define:

plasma

A

It is the liquid component of blood in which red and white blood cells are suspended.

Though primarily composed of water, plasma also contains proteins, glucose, hormones, electrolytes, and gases.

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6
Q

Which homeostatic function is most relevant to albumin?

A

osmoregulation

Albumin, the most common plasma protein, is produced in the liver and primarily maintains osmotic pressure. It also helps in buffering blood pH and acts to transport substances in the blood.

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7
Q

Name three substances or mechanisms that help regulate plasma volume.

A
  • osmotic pressure
  • antidiuretic hormone (ADH)
  • aldosterone

High plasma osmolarity draws water into the blood from the tissues; low plasma osmolarity causes water to flow out of the blood. Both ADH and aldosterone act on the kidneys, ADH by directly increasing water reabsorption and aldosterone by increasing the reabsorption of salt.

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8
Q

Define:

erythrocyte

A

Also known as red blood cells, these are the most common cells found in the blood. Their main responsibility is to carry oxygen to body tissues.

Red blood cells transport oxygen using hemoglobin.

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9
Q

In what part of the body are erythrocytes produced?

A

In the bone marrow from stem cells.

This process is referred to as erythropoiesis and is stimulated by decreased oxygen in the blood, which causes the kidneys to release erythropoietin (EPO).

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10
Q

What organs are responsible for the destruction of old and damaged erythrocytes?

A

The spleen and liver are the principal organs that destroy erythrocytes and process their parts.

When heme is broken down, iron is first released and recycled. The remainder of the molecule is converted into bilirubin, some of which becomes a component of bile and the rest of which is immediately excreted.

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11
Q

How do the kidneys respond to low oxygen levels in the blood?

A

The kidneys produce erythropoietin (EPO), which stimulates bone marrow to produce more red blood cells. This increases the oxygen carrying capacity of the blood.

Note that EPO is a peptide hormone.

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12
Q

Anemia is marked by a low value of what blood-related measurement?

A

Hematocrit

Hematocrit describes the percentage of a person’s total blood volume that is composed of red blood cells. A low hematocrit signifies that fewer RBCs are being produced, generally resulting in a decreased ability to transport oxygen.

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13
Q

What features characterize the structure of hemoglobin?

A

Hemoglobin has four protein subunits, each composed of a heme group and a globin protein. Together, these monomers form a hemoglobin tetramer.

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14
Q

To which part of blood does oxygen bind in order to be transported to tissue?

A

Oxygen binds to the iron in the heme group of hemoglobin, which is located in red blood cells.

Oxygen can travel in and out of a red blood cell via diffusion.

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15
Q

What conditions can alter the oxygen affinity of hemoglobin?

A

High temperature, low pH, and high carbon dioxide concentration lower the oxygen affinity of hemoglobin. This decrease allows oxygen to be more easily released to body tissue.

These conditions can be remembered as effects that occur during exercise, when the body is starved for oxygen. During such situations, hemoglobin must be able to readily drop off oxygen in the muscle and other tissue.

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16
Q

What term describes the basic shape of the oxygen-hemoglobin dissociation curve?

A

sigmoidal, or S-shaped

This shape stems from the ability of hemoglobin to utilize cooperative binding. Once a single oxygen molecule is bound, it becomes much easier for hemoglobin to bind to additional molecules, creating a steep slope.

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17
Q

What is the Bohr effect?

A

It states that the oxygen binding affinity of hemoglobin decreases as carbon dioxide concentration increases. In other words, O2 binding and plasma [CO2] are inversely related.

Since high CO2 concentration results in a lowered pH, acidic blood also correlates with lower binding affinity.

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18
Q

What happens to the oxygen binding curve of hemoglobin when a person exercises?

A

The curve shifts to the right.

A rightward shift represents a decrease in oxygen affinity. Exercise causes an increase in carbon dioxide, a drop in pH, and an increase in temperature, resulting in a lowered affinity for oxygen. This makes it easier to release the oxygen in muscle tissue.

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19
Q

Define:

myoglobin

A

It is the iron-containing protein that binds oxygen in skeletal muscle cells. It is closely related to hemoglobin, but contains only one monomer instead of four.

Because it picks up the oxygen that hemoglobin releases in the tissues, myoglobin has a higher O2 affinity than hemoglobin.

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20
Q

What is the basic shape of the oxygen binding curve of myoglobin?

A

hyperbolic

The myoglobin curve lacks a sigmoidal shape because, as a protein composed of a single subunit, it cannot undergo cooperative binding.

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21
Q

How do adult and fetal hemoglobin differ in their oxygen affinity?

A

Fetal hemoglobin has a greater affinity for oxygen than adult hemoglobin.

Specifically, fetal hemoglobin must be more prone to binding oxygen than maternal hemoglobin. This phenomenon allows a developing fetus to accept oxygen from its mother’s partially deoxygenated blood.

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22
Q

Define:

leukocyte

A

Also known as the white blood cell, it is an immune cell that combats infection in the body.

Unlike red blood cells, leukocytes do contain nuclei, and are also larger and less numerous.

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23
Q

Which main component of blood is required for proper clotting?

A

platelets

In addition to physically blocking lacerations, they activate proteins in the blood called clotting factors.

Platelets are not full cells, but tiny cell fragments derived from larger megakaryocytes. As such, they do not contain nuclei.

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24
Q

Name the primary protein responsible for blood clotting.

A

fibrin

Fibrin is derived from the soluble precursor fibrinogen.

Another protein, thrombin, cleaves fibrin into its active form. Thrombin also forms from a precursor, called prothrombin.

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25
Q

Which organ is responsible for producing clotting factors?

A

liver

These factors, including fibrinogen and prothrombin, circulate in the bloodstream and are activated by platelets after tissue damage.

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26
Q

Define:

coagulation

A

It is the process by which a liquid becomes a gel. When referring to blood, this process is also called clotting.

Coagulation functions to prevent immediate blood loss from a damaged vessel. It also facilitates eventual repair of the tissue.

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27
Q

How does the blood respond when the endothelium of a vessel is damaged?

A

First, platelets plug the area of the wound and activate a coagulation cascade. This pathway ends in the activation of fibrin from fibrinogen. Finally, fibrin forms an insoluble crosslinked mesh that seals the laceration.

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28
Q

How many oxygen molecules can be carried by one molecule of hemoglobin?

A

Hemoglobin has an iron-containing heme group for each of its four protein subunits, allowing it to carry four oxygen molecules total.

Each red blood cell, then, contains around 250 million molecules of hemoglobin, resulting in a carrying capacity of around one billion O2 molecules per erythrocyte.

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29
Q

In which form is most carbon dioxide carried in the blood?

A

Most carbon dioxide (70-80%) is carried in the form of bicarbonate ions, HCO3-. These ions comprise an integral part of the blood buffer system.

The remaining CO2 is either bound to hemoglobin or dissolved in its original form in the plasma.

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30
Q

Define:

antigen

A

It is a substance that causes an immune response. Specifically, antigens are markers that can be recognized by antibodies.

The surface proteins that determine blood type (A and B) are examples of antigens.

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31
Q

Which characteristic of an individual’s blood cells is used to identify blood type?

A

Blood type is classified based on the surface antigens present on a person’s erythrocytes.

Human blood types include A, B, AB, and O. While A and B denote possible antigens, an O blood type implies that neither is present.

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32
Q

With regard to blood type, what is the Rhesus factor?

A

Also known as the Rh factor, this refers to a surface antigen on human blood cells that was first discovered in Rhesus monkeys.

Rh positive (Rh+) blood displays the Rh antigen, while Rh negative (Rh-) blood lacks it. Rh- blood can be given to individuals of either blood type, while Rh+ blood is only given to other Rh+ people.

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33
Q

Define:

antibody

A

An immune protein that recognizes a specific, potentially harmful antigen or class of antigens. Antibodies are produced by B lymphocytes.

34
Q

What is significant about AB+ blood, and how does it differ from O- blood?

A
  • AB+ individuals are universal acceptors.
  • Those with O- blood are universal donors.

Since AB+ individuals have all the major surface antigens, they produce no antibodies and can accept blood of any type. In contrast, O- blood has no surface antigens and thus will not induce an immune response upon transfusion.

35
Q

What requirements must be met for one person to donate blood to another?

A

The donor blood must not contain surface antigens that are foreign to the recipient. In other words, the donated blood must not induce the production of antibodies.

36
Q

What requirements must be met for one person to receive blood from another?

A

The recipient must have all of the surface antigens that are present on the donated blood cells. This is necessary to prevent the production of antibodies.

For example, if the recipient is AB-, she can accept blood with either A or B antigens (or both). However, she cannot accept blood that contains the Rh factor.

37
Q

What occurs when a person is given a blood transfusion that contains foreign antigens?

A

In a process called hemagglutination, the recipient’s antibodies cause the transfused blood to bind and clump together.

38
Q

A man has a blood type of B-. Which antibodies could his immune system potentially produce?

A

Antibodies against the A and Rh antigens.

An individual’s blood type denotes which antigens are present on his red blood cells. Antibodies will be produced only for foreign antigens - in other words, those antigens that are not part of the blood type. B- blood contains only B antigens, so all others will be considered foreign.

39
Q

What blood types could a person with A+ blood receive?

A
  • A+
  • A-
  • O+
  • O-

Simply put, an A+ individual can receive blood as long as it does not contain antigens other than A and Rh. The only antigen that violates this rule is B, so the person could not receive B+, B-, AB+, or AB- blood.

40
Q

A mother with Rh- blood becomes pregnant with her first child, who is found to have a blood type of Rh+. What complications could occur?

A

The mother may develop antibodies against the Rh factor, which could affect future pregnancies.

Since fetal and maternal blood are separated, development of antibodies usually does not occur until birth. The first baby, then, will be unaffected. However, if the mother becomes pregnant with a second Rh+ fetus, her antibodies may attack its cells. This is known as hemolytic disease of the newborn, or erythroblastosis fetalis.

41
Q

What are the main functions of the circulatory system?

A
  • Circulate oxygen, nutrients, hormones, fluids, and ions to body tissues.
  • Remove carbon dioxide.
  • Remove metabolic wastes, such as urea.
  • Aid in thermoregulation.
42
Q

How does the circulatory system regulate body temperature?

A

Blood vessels can undergo vasoconstriction and vasodilation.

In cold temperatures, arterioles near the skin become narrow, or constrict, to limit heat loss. In hot temperatures, arterioles widen, or dilate, to allow heat to dissipate from the body’s surface.

43
Q

Which type of muscle allows for variation in blood vessel diameter depending on the ambient temperature?

A

Smooth muscle lining the arteries and arterioles allows vasodilation and vasoconstriction to occur.

Since smooth muscle is controlled by the autonomic nervous system, these thermoregulatory functions are involuntary.

44
Q

On a cold winter day, a woman leaves her office and begins a long walk to her car. How would her blood vessels respond?

A

Surface arterioles would vasoconstrict, reducing blood flow to the skin in an attempt to conserve heat.

Long periods of vasoconstriction are usually interrupted by brief vasodilatory cycles to avoid the excessive restriction of blood flow.

45
Q

At 1 PM on a hot summer afternoon, a teenager goes outside to sunbathe. How would his blood vessels respond?

A

Surface arterioles would vasodilate, carrying blood close to the external environment in an attempt to dissipate heat.

Vasodilation can explain the flushed red face of a person who has become overheated.

46
Q

Describe the general structure of the human heart.

A

A human heart has four chambers, with the left and the right atrium positioned above the left and the right ventricle. The atria and ventricles are separated by valves.

The right side of the heart contains deoxygenated blood, while blood on the left side is oxygenated.

47
Q

What structural and functional differences distinguish an atrium from a ventricle?

A

Structurally, atria are smaller and located superior to the ventricles. Functionally, atria receive blood that returns to the heart and pump it to the ventricles, while ventricles pump blood to the rest of the body.

48
Q

In order, list the structures that blood will contact between the vena cava and the aorta. Do not include valves.

A

After returning to the heart via the vena cava, blood will contact the:
1. Right atrium
2. Right ventricle
3. Pulmonary artery
4. Lung
5. Pulmonary vein
6. Left atrium
7. Left ventricle

From the left ventricle, it exits the heart through the aorta.

49
Q

Name the two valves in the heart that separate an atrium from a ventricle.

A
  1. The tricuspid valve is situated between the right atrium and the right ventricle.
  2. The bicuspid or mitral valve separates the left atrium from the left ventricle.

Both of these structures are classified as atrioventricular valves.

50
Q

After blood is oxygenated in the lungs, which vessel carries it back to the heart?

A

pulmonary vein

Unlike the vast majority of venous circulation, the pulmonary vein carries oxygenated blood. Remember that veins are defined as vessels that transport blood toward the heart, not as vessels that carry oxygen-depleted blood.

51
Q

A certain heart malformation prevents the mitral valve from closing properly. How would this condition affect blood flow?

A

Some of the blood leaving the left atrium would leak back in instead of fully progressing to the left ventricle.

Such defects can cause the heart to work harder to counteract the defective valve, causing stress and long-term impairments in blood flow.

52
Q

Define:

systolic pressure

A

The blood pressure measured when the ventricles are contracting and blood is being pumped.

Of the two pressure measurements, systolic pressure is larger and is given as the numerator. In the standard reading of “120 over 80,” the systolic pressure is 120 mmHg.

53
Q

Define:

diastolic pressure

A

The blood pressure measured when the ventricles are relaxed and no blood is being pumped.

Of the two pressure measurements, diastolic pressure is smaller and is given as the denominator. In the standard reading of “120 over 80,” the diastolic pressure is 80 mmHg.

54
Q

Name the main components present in arterial walls.

A

Arteries have thick walls that contain endothelium, elastic connective tissue, and smooth muscle.

The elastic fibers allow arteries to stretch in diameter, while smooth muscle functions in vasoconstriction and vasodilation.

55
Q

What are the two major types of arteries, and where is each type located in the circulatory system?

A

Arteries are classified as either elastic or muscular.

Elastic arteries are those that attach directly to the heart, namely the aorta and pulmonary artery. Muscular arteries are more distant from the heart and carry blood to systemic organs.

56
Q

Describe the structural differences between elastic and muscular arteries.

A
  • Elastic arteries contain more connective fibers, such as collagen and elastin. This allows for expansion to accomodate blood that is pumped from the heart.
  • Muscular arteries contain more smooth muscle, as they need to constrict or dilate to control blood flow to a specific region of the body.
57
Q

What is the function of arterioles?

A

They connect directly to arteries and control blood flow to the capillaries. Structurally, they are smaller than arteries but otherwise similar.

Arterioles are the primary site of vasoconstriction.

58
Q

Describe the similarities between arterial and venous walls.

A

Like arteries, veins contain an inner lining of endothelium, as well as smooth muscle and connective tissue.

59
Q

Describe the differences between arterial and venous walls.

A

Venous walls are thinner than arterial walls. As a result, the lumen or interior of a vein is larger than that of an artery, allowing it to hold more blood.

Specifically, veins contain less elastic tissue and less smooth muscle than arteries. Veins also have one-way valves, which prevent blood from traveling away from the heart.

60
Q

What is the function of venules?

A

They collect blood from the capillaries and carry it to the veins. Structurally, they are smaller than veins but otherwise similar.

61
Q

Which type of vessel connects arterioles to venules?

A

Capillaries

Capillaries, the smallest and most numerous blood vessels, arise from arterioles and converge into venules. They form the site of gas and nutrient exchange with the tissues.

62
Q

Which process provides the pressure that propels blood into arteries?

A

Contraction of the ventricles.

Vasoconstriction can also alter blood pressure and control the flow of blood to specific tissues; however, it occurs mainly in the arterioles.

63
Q

Which process provides the pressure that carries blood back to the heart through veins?

A

The contraction of nearby skeletal muscle compresses veins, propelling blood forward. Veins can also alter their pressure by constricting or dilating.

In the lower part of the body, gravity opposes proper venous blood flow. To prevent blood from traveling backwards, veins contain one-way valves.

64
Q

Which type of blood vessel has the lowest pressure?

A

Veins

Pressure is highest in the arteries and decreases in the same order as the circulatory structure itself: arterioles, capillaries, venules, veins.

65
Q

In which type of vessel does blood flow the slowest?

A

In the capillaries.

According to the continuity equation, fluid velocity and cross-sectional area of a vessel are inversely related. Since all of the body’s capillaries combine to have an extremely large area, blood moves through them slowly.

66
Q

A student observes a circulatory structure that is lined with endothelium, has valves, and can vasoconstrict. Which type of blood vessel is this?

A

vein

Only veins have valves to prevent backflow. Arteries, veins, and arterioles can all vasoconstrict to some degree, and all blood vessels possess endothelium.

67
Q

A student observes a circulatory structure that directly connect to capillaries, carries blood away from the heart, and can vasoconstrict. Which type of blood vessel is this?

A

arteriole

Only venules and arterioles directly connect to the capillaries, and only the arterial system carries blood away from the heart. Arterioles often control their diameter via vasoconstriction.

68
Q

What is the primary difference between pulmonary and systemic vessels?

A

Systemic veins carry deoxygenated blood, while systemic arteries contain blood that has been oxygenated. The reverse is true for pulmonary circulation.

Pulmonary circulation refers to bloodflow between the heart and the lungs, while systemic circulation provides blood to the rest of the body.

69
Q

What function do capillary beds serve?

A

They provide a site where oxygen, carbon dioxide, nutrients, and wastes are exchanged between blood and interstitial fluid.

70
Q

Which two opposing pressures control the movement of fluid between capillaries and tissues?

A
  • Hydrostatic pressure
  • Osmotic pressure

Hydrostatic pressure is synonymous with blood pressure and promotes the movement of fluid out of the capillaries. Osmotic pressure is controlled by solute concentration and promotes the return of fluid from the tissues.

71
Q

What name is given to osmotic pressure that is specifically produced by proteins?

A

Oncotic pressure

In the circulatory system, proteins have a unique ability to generate osmotic pressure, since they are too large to leave the capillaries. Albumin is a notable example of such a protein.

72
Q

Which transport method is used in the capillary exchange of most gases and solutes?

A

diffusion

In general, diffusion is favored by small, nonpolar substances.

Oxygen and nutrients flow from the blood, where their concentration is relatively high, to the interstitial fluid. Carbon dioxide and waste flow from the insterstitial fluid to the blood.

73
Q

How is the circulatory system involved in thermoregulation?

A

Vasoconstriction and vasodilation function to control body temperature. In hot conditions, vessels dilate to bring blood close to the outside environment and facilitate heat loss. Cold conditions promote constriction to keep blood close to the warmer core.

Indirectly, plasma also provides fluid that diffuses into the interstitium and eventually comprises sweat.

74
Q

How do capillary walls differ from the walls of other types of blood vessels?

A

Capillary walls consist only of a single layer of endothelium. This thin-walled structure facilitates the diffusion of gases and solutes.

Since capillaries do not contain smooth muscle, they cannot vasoconstrict.

75
Q

In which part of a capillary bed does hydrostatic pressure predominate?

A

At the arterial end, closest to the heart.

Since hydrostatic pressure is simply another name for blood pressure, it is highest at the beginning of a capillary bed. As fluid is pushed outward, it decreases and eventually is surpassed by osmotic pressure.

76
Q

Which type of pressure would be disrupted by a condition that introduced large holes or gaps to capillary walls?

A

Osmotic, or oncotic, pressure.

Osmotic pressure in a capillary bed is maintained by proteins, which are too large to leave the vessels. If capillary walls became more permeable to large molecules, this function would be altered, disrupting the flow of fluid back into the capillary.

77
Q

What is/are the site(s) of blood oxygenation and detoxification in the fetus, and how does this differ from adult circulation?

A

In adult circulation, gas exchange occurs within the lungs, while detoxification of blood is performed by the liver. In the fetus, both of these functions are performed by the placenta.

For this reason, adaptations of the fetal circulatory system exist to bypass both the lungs and the liver.

78
Q

Which structures are connected by the ductus arteriosus?

A

The ductus arteriosus directly connects the pulmonary artery to the aorta.

Much of fetal blood does not even reach the pulmonary artery, but this adaptation ensures that any blood that does reach this vessel will still bypass the lungs.

79
Q

Which structures are connected by the ductus venosus?

A

The ductus venosus directly connects the umbilical vein to the inferior vena cava.

This adaptation allows oxygenated blood from the placenta to bypass the liver.

80
Q

What is the function of the foramen ovale?

A

This is a hole between the fetal atria that allows oxygenated blood to travel directly from the right atrium to the left atrium. (Normally, in adults, the blood in the right atrium is deoxygenated. In a fetus, however, this blood was already oxygenated in the placenta.)

Along with the ductus arteriosus, the foramen ovale causes fetal blood to bypass the lungs.

81
Q

Why are adaptations to fetal pulmonary circulation necessary?

A

Fetal lungs are underdeveloped and fluid-filled, so they are bypassed by fetal circulation. Additionally, a fetus receives oxygen from maternal blood, not the external environment; this renders the lungs unnecessary.

82
Q

What may occur if the ductus arteriosus does not close properly after birth?

A

Oxygenated blood from the aorta may flow back to the lungs, resulting in high pulmonary pressure and difficulty breathing.

This condition is known as “patent ductus arteriosus” and can lead to congestive heart failure.