Fundamentals of Blood and Red Blood Cells

Question 1

What is the circulatory system?

Answer 1

The circulatory system is a network of vessels through which blood moves around the body.

Question 2

What are the two main components of blood?

Answer 2

Blood has a cellular component and an extracellular matrix liquid component known as blood plasma.

Question 3

What is the color of blood plasma?

Answer 3

Blood plasma is yellow in color.

Question 4

What are the main constituents of blood plasma?

Answer 4

The main constituents of blood plasma are water (92%), biomolecules (proteins, hormones, carbohydrates), and inorganic compounds such as salts (8%).

Question 5

What is the function of blood plasma?

Answer 5

Blood plasma transports various substances, including metabolites (products of cellular metabolism).

Question 6

What percentage of water is found in blood plasma?

Answer 6

Approximately 92% of blood plasma consists of water.

Question 7

What are some examples of biomolecules found in blood plasma?

Answer 7

Biomolecules found in blood plasma include proteins, hormones, and carbohydrates.

Question 8

Apart from cells and plasma, what other substances are transported by blood?

Answer 8

Blood also transports metabolites, which are the byproducts of cellular metabolism.

Question 9

What is the role of inorganic salts in blood plasma?

Answer 9

Inorganic salts help buffer the pH of blood, contribute to osmotic balance, and regulate the cell membrane potential.

Question 10

What is the function of blood plasma in transporting nutrients?

Answer 10

Blood plasma transports nutrients such as glucose and vitamins throughout the body.

Question 11

What substances are transported by blood plasma?

Answer 11

Blood plasma transports proteins, hormones, and antibodies throughout the body.

Question 12

What is the role of blood plasma in removing waste compounds?

Answer 12

Blood plasma helps remove metabolic waste compounds from the body.

Question 13

How do inorganic salts contribute to osmotic balance?

Answer 13

Inorganic salts in blood plasma help maintain the proper concentration of solutes inside and outside of cells, ensuring osmotic balance.

Question 14

Why is pH regulation important in blood plasma?

Answer 14

pH regulation is essential for maintaining the proper functioning of enzymes and overall cellular processes.

Question 15

Which component of blood plasma is responsible for transporting antibodies?

Answer 15

Blood plasma transports antibodies, which are crucial for the immune response.

Question 16

Besides nutrients, what other substances does blood plasma transport?

Answer 16

In addition to nutrients, blood plasma transports various biomolecules, gases, waste products, and regulatory substances throughout the body.

Question 17

What is the main function of red blood cells (erythrocytes)?

Answer 17

The main function of red blood cells is to transport oxygen (O2) and carbon dioxide (CO2) throughout the body.

Question 18

What is the term used to describe the percentage of red blood cells in the total blood volume?

Answer 18

The percentage of red blood cells relative to the total blood volume is called the “hematocrit.”

Question 19

What are the different types of white blood cells (leukocytes)?

Answer 19

the different types of white blood cells are basophils, eosinophils, neutrophils, lymphocytes, and monocytes.

Question 20

What is the function of white blood cells?

Answer 20

White blood cells are part of the immune system and play a role in defending the body against infections and foreign substances.

Question 21

What is the role of platelets in blood?

Answer 21

Platelets are essential for blood clotting, preventing excessive bleeding.

Question 22

Are platelets considered cells?

Answer 22

No, platelets are not cells but rather cytoplasmic cell fragments derived from cellular precursors.

Question 23

How would you describe the shape of red blood cells?

Answer 23

Red blood cells have a characteristic “flexible disc” or “doughnut” shape that is biconcave.

Question 24

What is the advantage of the biconcave shape of red blood cells?

Answer 24

The biconcave shape of red blood cells allows them to travel through blood vessels, including narrow capillaries. It also provides a large surface area for efficient gas exchange.

Question 25

Do human red blood cells have a nucleus?

Answer 25

No, human red blood cells do not have a nucleus.

Question 26

Are there any exceptions to the lack of nucleus in red blood cells?

Answer 26

Yes, there are exceptions in some mammals and all other vertebrate species where red blood cells do have a nucleus.

Question 27

How do human red blood cells differ in terms of organelles and cellular membrane structures?

Answer 27

Human red blood cells have a reduced number of organelles and cellular membrane structures compared to other cells.

Question 28

What happens to older red blood cells?

Answer 28

Older red blood cells rupture easily, and the debris left behind is degraded by macrophages, which are immune system cells.

Question 29

How is the composition of the red blood cell plasma membrane asymmetrical?

Answer 29

The red blood cell plasma membrane is asymmetrical, with mainly negatively charged phospholipids located on the inner part of the lipid bilayer.

Question 30

What is the significance of the asymmetrical composition of the red blood cell plasma membrane?

Answer 30

The asymmetrical composition is important for cell signaling and communication.

Question 31

How is the biconcave shape of red blood cells achieved?

Answer 31

The biconcave shape of red blood cells is achieved through a mesh-like network formed by the protein spectrin.

Question 32

What is the role of spectrin in red blood cells?

Answer 32

Spectrin, a filamentous protein (~100 nm), is the primary component of the red blood cell cytoskeleton. It interacts with cell membrane proteins and helps maintain the biconcave shape of red blood cells.

Question 33

What happens when there are abnormalities in the spectrin gene?

Answer 33

Abnormalities in the spectrin gene can lead to the production of spherical and fragile red blood cells.

Question 34

How are platelets released?

Answer 34

Platelets are released by megakaryocytes, which are large cells found in the bone marrow.

Question 35

What role do enzymes in platelets play?

Answer 35

Enzymes in platelets help initiate the process of blood clotting.

Question 36

What happens when circulating platelets come in contact with collagen fibers in damaged blood vessels?

Answer 36

When platelets come in contact with collagen fibers, they undergo swelling and form a “sticky patch,” initiating the blood clotting cascade.

Question 37

What is the role of inactivated precursor proteins in blood clotting?

Answer 37

Blood clotting relies on inactivated precursor proteins, such as prothrombin and fibrinogen, which are produced in the liver and circulate in the blood.

Question 38

How are inactivated precursor proteins involved in clotting?

Answer 38

Inactivated precursor proteins are cleaved into active forms, thrombin and fibrin, respectively, which are essential for the formation of blood clots.

Question 39

What occurs after the formation of a blood clot during wound healing?

Answer 39

Following the formation of a blood clot, wound healing progresses with the formation of scar tissue.

Question 40

Where does hematopoiesis occur in humans?

Answer 40

Hematopoiesis, the process of blood cell formation, occurs in the bone marrow throughout life.

Question 41

What is the role of bone marrow in hematopoiesis?

Answer 41

Bone marrow ensures a constant supply of red blood cells (RBCs) at a rate of approximately 3.5 x 10^11 per day.

Question 42

How much blood does the average adult have, taking into account the average hematocrit?

Answer 42

The average adult has approximately 5,000 ml of blood, with half or 2,250 ml consisting of red blood cells, considering the average healthy hematocrit.

Question 43

What is the average daily blood production of red blood cells for a healthy adult?

Answer 43

The average daily blood production of red blood cells for a healthy adult is estimated to be 18.75 ml/day.

Question 44

Where does erythropoiesis, the specific process of red blood cell production, take place?

Answer 44

Erythropoiesis occurs in the hematopoietic or red marrow, which is located within the trabecular (spongy) bone at the ends of long bones.

Question 45

What happens after hemoglobin synthesis is completed in erythroblasts?

Answer 45

After hemoglobin synthesis is completed, the nucleus of the erythroblast, which has been progressively condensing, is expelled, yielding a reticulocyte.

Question 46

What happens to reticulocytes after they are formed?

Answer 46

Reticulocytes enter the vascular circulation and mature into erythrocytes within a span of 1 to 3 days.

Question 47

How many reticulocytes are typically found in the blood circulation of a healthy individual?

Answer 47

A healthy individual typically has approximately 25 to 125 x 10^9/L reticulocytes in their blood circulation.

Question 48

What does an elevated number of reticulocytes indicate?

Answer 48

An elevated number of reticulocytes suggests an active bone marrow response to blood loss, such as trauma or anemia. It is a compensatory mechanism.

Question 49

How can reticulocytes be visualized?

Answer 49

Reticulocytes can be visualized using a supravital stain. In the staining, the blue dots represent ribosomes within the reticulocytes.

Question 50

What is the composition of adult hemoglobin (HbA)?

Answer 50

Adult hemoglobin (HbA) consists of four subunits: two identical α chains and two identical β chains.

Question 51

What is the composition of fetal hemoglobin (HbF)?

Answer 51

Fetal hemoglobin (HbF) consists of two identical α chains and two identical γ chains.

Question 52

What is the main secondary structure of the hemoglobin protein subunits?

Answer 52

The main secondary structure of the hemoglobin protein subunits is the α-helix.

Question 53

How many heme groups are bound to each hemoglobin subunit?

Answer 53

Each hemoglobin subunit binds to a heme group, and there are four heme groups in total (shown in green) within the hemoglobin molecule.

Question 54

What is the role of hemoglobin?

Answer 54

Hemoglobin binds to and transports oxygen (O2) throughout the body.

Question 55

How does the oxygen binding affinity differ between HbA and HbF?

Answer 55

HbF (fetal hemoglobin) exhibits a stronger binding affinity for oxygen than HbA (adult hemoglobin).

Question 56

What is responsible for the red color of hemoglobin?

Answer 56

The heme group within hemoglobin is responsible for its red color.

Question 57

What does the heme group consist of?

Answer 57

The heme group consists of four pyrrole rings that form a tetrapyrrole ring called protoporphyrin.

Question 58

What is the role of the heme group in oxygen binding?

Answer 58

Each of the nitrogen atoms in the pyrrole rings of the heme group participates in the binding of a Fe atom (Fe2+), which is responsible for binding oxygen.

Question 59

What happens when oxygen binds to the heme group?

Answer 59

When oxygen binds to the heme group, there is a partial transfer of an electron from Fe to O2, resulting in the formation of Fe3+ and a superoxide ion (O2-), which is a reactive oxygen species.

Question 60

How does hemoglobin ensure the release of O2 rather than O2- in tissues?

Answer 60

The haemoglobin protein subunits are structured in a way that favors the release of O2 rather than O2- in tissues, preventing the buildup of reactive oxygen species.

Question 61

What does the S-like shape of the hemoglobin binding curve indicate?

Answer 61

The S-like shape of the hemoglobin binding curve indicates cooperative binding behavior, where the binding of oxygen to one heme group increases the likelihood of oxygen binding to the other three heme groups.

Question 62

How does cooperative binding assist in the unloading of oxygen?

Answer 62

Cooperative binding behavior ensures that when one heme group releases oxygen, it assists in the unloading of oxygen from the other three heme groups, promoting efficient oxygen release.

Question 63

Where does strong oxygen binding occur in hemoglobin?

Answer 63

Strong oxygen binding occurs in the lungs, where the partial pressure of oxygen is approximately 100 torr.

Question 64

Where is oxygen easily released from hemoglobin?

Answer 64

Oxygen is easily released from hemoglobin in the tissues, where the partial pressure of oxygen is much lower, approximately 20 torr.

Question 65

Why is cooperative binding behavior important for hemoglobin’s function?

Answer 65

Cooperative binding behavior allows hemoglobin to efficiently bind oxygen in the lungs and readily release it in the oxygen-depleted tissues, ensuring effective oxygen transport.

Question 66

How does 2,3-BPG affect the affinity of hemoglobin for oxygen?

Answer 66

2,3-BPG lowers the affinity of hemoglobin for oxygen, ensuring the release of oxygen in tissues.

Question 67

How does 2,3-BPG function as an allosteric regulator of hemoglobin?

Answer 67

2,3-BPG binds to a specific site in the center of the hemoglobin tetramer, which is different from the oxygen-binding sites. This binding causes a conformational change in hemoglobin, resulting in a lower oxygen-binding affinity

Question 68

What is the consequence of 2,3-BPG binding to hemoglobin?

Answer 68

When 2,3-BPG binds to hemoglobin, it promotes a conformation that has a lower affinity for oxygen, leading to the occupancy of more oxygen binding sites. This lower oxygen binding affinity ensures easier release of oxygen in the tissues.

Question 69

How does 2,3-BPG contribute to efficient oxygen delivery?

Answer 69

By lowering the oxygen affinity of hemoglobin, 2,3-BPG facilitates the release of oxygen from hemoglobin in the tissues, enabling efficient oxygen delivery to the cells.

Question 70

What is the nucleotide sequence similarity between the genes for the β chain (HbA) and the γ chain (HbF)?

Answer 70

The genes for the β chain (HbA) and the γ chain (HbF) share 72% nucleotide sequence similarity.

Question 71

How does the binding of 2,3-BPG differ between HbF and HbA?

Answer 71

Due to their nucleotide sequence differences, 2,3-BPG does not bind as efficiently to HbF as it binds to HbA. Therefore, HbF has a lower affinity for 2,3-BPG compared to HbA.

Question 72

Do fetal red blood cells (RBCs) have a higher affinity for oxygen than maternal RBCs?

Answer 72

Yes, fetal RBCs have a higher affinity for oxygen than maternal RBCs due to the presence of HbF, which exhibits stronger oxygen binding.

Question 73

How is oxygen efficiently transferred from maternal RBCs to fetal RBCs?

Answer 73

During embryonic development, oxygen can be efficiently transferred from maternal RBCs to fetal RBCs due to the higher affinity of fetal HbF for oxygen. This allows for optimal oxygen exchange between the maternal and fetal circulatory systems.

Question 74

What is the purpose of cellular respiration?

Answer 74

The purpose of cellular respiration is to generate energy in the form of ATP by breaking down glucose and utilizing oxygen.

Question 75

What is fermentation?

Answer 75

Fermentation is an alternative metabolic pathway that occurs in the absence of oxygen. It involves the breakdown of glucose into lactic acid (lactate) and a small amount of ATP.

Question 76

Where does fermentation take place and when does it occur?

Answer 76

Fermentation takes place in muscle cells, especially during intense exercise when the demand for ATP is higher than the rate at which oxygen can be transported. It serves as a rapid source of ATP production.

Question 77

What are the consequences of lactate buildup during fermentation?

Answer 77

Lactate buildup leads to a lowering of pH, causing muscle fatigue and discomfort.

Question 78

What is the structure of myoglobin?

Answer 78

Myoglobin has the same structure as one hemoglobin subunit and contains one heme group.

Question 79

Where is myoglobin present?

Answer 79

Myoglobin is present in skeletal muscle cells.

Question 80

What is the role of myoglobin?

Answer 80

Myoglobin ensures oxygen diffusion within skeletal muscle cells, serving as a storage and transport molecule for oxygen.

Question 81

How does myoglobin’s affinity for oxygen compare to that of hemoglobin?

Answer 81

Myoglobin has a higher affinity for oxygen compared to hemoglobin. It binds oxygen more tightly.

Question 82

What is the consequence of myoglobin’s high oxygen affinity?

Answer 82

The high oxygen affinity of myoglobin results in inefficient or low oxygen release to the tissues.

Question 83

How does the oxygen-carrying capacity of myoglobin compare to hemoglobin?

Answer 83

Hemoglobin can deliver approximately 10 times more oxygen to tissues compared to myoglobin due to its cooperative binding behavior and ability to release oxygen more readily.

Question 84

What happens when carbon monoxide (CO) binds to hemoglobin?

Answer 84

Carbon monoxide binds to hemoglobin at the oxygen binding site, forming carboxyhemoglobin.

Question 85

How does carbon monoxide binding differ from oxygen binding to hemoglobin?

Answer 85

Carbon monoxide binds very tightly to hemoglobin, approximately 200 times stronger than oxygen, which leads to the displacement of bound oxygen molecules.

Question 86

What is the consequence of carbon monoxide binding to hemoglobin?

Answer 86

When carbon monoxide binds to hemoglobin, it increases hemoglobin’s affinity for oxygen, resulting in the reduced release of oxygen in the tissues.

Question 87

What are the symptoms of carbon monoxide poisoning?

Answer 87

Carbon monoxide poisoning can cause symptoms such as disorientation, nausea, lethargy, and weakness.

Question 88

How is carbon monoxide poisoning treated?

Answer 88

Hyperbaric oxygen therapy is a treatment option for carbon monoxide poisoning. It involves administering 100% oxygen at a higher atmospheric pressure to enhance oxygenation and promote the removal of carbon monoxide from hemoglobin.

Question 89

What is hypovolemia?

Answer 89

Hypovolemia refers to a condition characterized by a loss of extracellular fluid, specifically a decrease in blood volume.

Question 90

What are the causes of hypovolemia?

Answer 90

Hypovolemia can be caused by various factors, including excess bleeding due to trauma, diarrhea or vomiting, renal failure, and the use of diuretics.

Question 91

What are the symptoms of hypovolemia?

Answer 91

Symptoms of hypovolemia include fatigue, headaches, cyanosis (bluish discoloration of the skin), and tachycardia (rapid heart rate).

Question 92

What percentage of blood volume loss is indicated by the symptoms mentioned?

Answer 92

The symptoms mentioned are consistent with more than a 10% loss of blood volume.

Question 93

What can happen if hypovolemia is left untreated?

Answer 93

If left untreated, hypovolemia can lead to hypovolemic shock, organ failure, and even death.

Question 94

What is anemia?

Answer 94

Anemia is a condition characterized by a reduced concentration of hemoglobin, leading to a decreased ability of the blood to transport oxygen.

Question 95

What are the clinical symptoms of anemia?

Answer 95

Clinical symptoms of anemia include tachycardia (rapid heart rate), breathlessness, pallor (pale skin), and lethargy (fatigue and weakness).

Question 96

What are the causes of anemia?

Answer 96

Anemia can be caused by various factors, including iron deficiency (common in pregnancy and childbirth), bone marrow suppression (e.g., myelodysplastic syndrome, aplastic anemia), blood loss, folate deficiency, vitamin B12 deficiency (pernicious anemia), hemolysis (hemolytic anemia), inherited problems in hemoglobin synthesis (e.g., β-thalassemia), and autoimmune disorders.

Question 97

What are some examples of inherited problems in hemoglobin synthesis?

Answer 97

One example of an inherited problem in hemoglobin synthesis is β-thalassemia, which affects the production of the β chain of hemoglobin.

Question 98

How can autoimmune disorders contribute to anemia?

Answer 98

Autoimmune disorders can cause anemia by triggering the immune system to attack and destroy red blood cells.

Question 99

What causes sickle cell anemia?

Answer 99

Sickle cell anemia is caused by a single mutation in the β-globin gene, where the amino acid glutamate at position 6 is replaced with valine. This mutation leads to the production of abnormal hemoglobin called HbS.

Question 100

What happens to hemoglobin in sickle cell anemia?

Answer 100

In sickle cell anemia, oxyhemoglobin (oxygenated form of hemoglobin) is not affected, but deoxyhemoglobin (deoxygenated form) forms fibrous aggregates, resulting in the characteristic sickle-like shape of red blood cells.

Question 101

How does the sickle-like shape of red blood cells affect blood flow?

Answer 101

The sickle-like shape of red blood cells in sickle cell anemia can cause clogging of capillaries and hinder smooth blood flow. These abnormal red blood cells also stick frequently to vessel walls, leading to further complications.

Question 102

What is the result of reduced circulation time for sickle cell anemia?

Answer 102

Due to their abnormal shape and reduced lifespan, red blood cells in sickle cell anemia have a shorter circulation time, leading to a decreased oxygen-carrying capacity and other complications.

Question 103

What are some symptoms and complications of sickle cell anemia?

Answer 103

Symptoms and complications of sickle cell anemia include severe pain crises, organ damage, increased susceptibility to infections, anemia-related fatigue, and various other health issues.

Question 104

What causes α-thalassemia?

Answer 104

α-thalassemia is caused by the deletion or inactivation of three or four of the α-globin genes. The deletion or inactivation of one or two genes typically does not cause symptoms.

Question 105

What is the result of the deletion or inactivation of all four α-globin genes?

Answer 105

Deletion or inactivation of all four α-globin genes leads to a condition called Hb Bart’s syndrome, which is usually lethal in the embryonic stage.

Question 106

What is HbH disease?

Answer 106

HbH disease is a form of α-thalassemia resulting from the deletion or inactivation of three α-globin genes. It is characterized by symptoms such as enlarged spleen and liver, anemia (sometimes requiring blood transfusions), and hemolysis (premature destruction of red blood cells).

Question 107

What causes β-thalassemia?

Answer 107

β-thalassemia is caused by mutations or deletions of the β-globin gene, which affects the production of β-globin chains.

Question 108

What are the symptoms and complications of β-thalassemia?

Answer 108

β-thalassemia is characterized by symptoms such as anemia, hemolysis, erythroid hyperplasia (overproduction of red blood cells), bone marrow expansion, and extramedullary hematopoiesis (production of blood cells outside the bone marrow).

Question 109

What is aplastic anemia?

Answer 109

Aplastic anemia is a condition characterized by bone marrow failure, resulting in impaired hematopoiesis (formation of blood cells). It leads to pancytopenia, which is a reduction in the number of red blood cells, white blood cells, and platelets.

Question 110

What are the symptoms of aplastic anemia?

Answer 110

Symptoms of aplastic anemia include fatigue, weakness, shortness of breath, pale skin, frequent infections, and easy bruising or bleeding.

Question 111

What is Fanconi anemia?

Answer 111

Fanconi anemia is a rare genetic disorder characterized by bone marrow failure, congenital abnormalities, and an increased risk of developing certain cancers.

Question 112

What are the symptoms of Fanconi anemia?

Answer 112

Symptoms of Fanconi anemia can vary but often include bone marrow failure, physical abnormalities (such as skeletal, kidney, and heart defects), growth problems, and an increased susceptibility to cancers (such as leukemia).

Question 113

How is aplastic anemia and Fanconi anemia managed?

Answer 113

The management of aplastic anemia and Fanconi anemia is complex and may involve treatments such as blood transfusions, medications to suppress the immune system, and, in some cases, bone marrow transplantation. Regular medical monitoring and support are necessary for individuals with these conditions.

Question 114

What is polycythemia?

Answer 114

Polycythemia is a condition characterized by an elevated hematocrit, which refers to an increased percentage of red blood cells in the blood.

Question 115

What are the possible causes of polycythemia?

Answer 115

Polycythemia can be caused by a decrease in blood volume or an increased production of red blood cells entering circulation, known as erythrocytosis. It can also be associated with gene mutations affecting the JAK-STAT signaling pathway or malfunction of erythropoietin (EPO) and its receptor.

Question 116

What are the symptoms of polycythemia?

Answer 116

Symptoms of polycythemia may include fatigue, dizziness, headaches, gum bleeding, and nosebleeds. In more severe cases, it can affect heart, spleen, and blood clotting.

Question 117

What is myeloproliferative neoplasm?

Answer 117

Myeloproliferative neoplasms are a group of disorders characterized by the overproduction of blood cells in the bone marrow. Polycythemia is an example of a myeloproliferative neoplasm, while thrombocythemia refers to an increased number of platelets.

Question 118

How is polycythemia managed?

Answer 118

The management of polycythemia aims to reduce blood volume and control the production of red blood cells. This may involve therapeutic phlebotomy (removal of blood), medications to suppress bone marrow activity, and addressing the condition’s underlying causes.