BIOS255 Exam 1 Study Guide PDF

Summary

This document is a study guide for an exam covering the cardiovascular system and blood composition. It includes details about different parts of blood, such as plasma and erythrocytes, along with their functions and related disorders. The document also covers hemoglobin and the process of blood cell formation.

Full Transcript

BIOS255 EXAM1 STUDY GUIDE
Introduction - General functions of cardiovascular System and composition of Blood

Different parts to centrifuged blood and what is in each part:
o Plasma – Upper layer- 55% (water, dissolved gasses, nutrients, waste products,
proteins)-
o Buffy Coat – middle layer- less than 1% (WBCs and Platelets)
o Hematocrit (Erythrocyte) – lowermost layer- 45% (RBC)
Three formed elements found in blood
o RBCs (Erythrocytes): 4.2 – 6.2 million/µL
o WBCs (Leukocytes): 5,000 – 10,000/µL
o Platelets: 130,000 – 360,000/µL
Blood Plasma
plasma makes up over half of blood volume. It is a complex mixture of water, nutrients,
hormones, electrolytes (like Na+, K+), gases, nitrogenous wastes (urea), and proteins.
Plasma proteins are mainly produced by liver and exert the greatest effect on the physical
characteristics of whole blood.
The major plasma proteins in blood include albumin, globulins, and fibrinogen.
Albumin constitutes 60% influences the viscosity and osmolarity of blood

Globulins make up 36% of plasma proteins, are antibodies secreted to combat
pathogens in specialized immune responses.

Fibrinogen constitutes about 4% of all plasma proteins. It is a soluble precursor
of another protein called fibrin.
blood plasma - fibrinogen = blood serum.

Introduction to Erythrocytes, their role, homeostasis, disorders, blood groups and clinical
significance

Red Blood Cells (RBCs) – lack a nucleus, biconcave disc shape, bags of hemoglobin,
carry oxygen and some carbon dioxide
Hct- hematocrit- % of whole blood occupied by RBC.
o Formed in the red bone marrow from the hematopoietic stem cell, myeloid stem
cell, erythroblast, reticulocyte, mature RBC
▪ To make an RBC you need: EPO or erythropoietin (released from kidney
due to low oxygen in the blood – hypoxemia); amino acids; iron (ferrin);
vitamin B12
▪ The steps to hemoglobin recycling: functions of bilirubin, biliverdin,
stercobilin, urobilinogen, and transferrin
▪ Hemoglobin is made up of iron (4 heme groups)- binds to oxygen and
globin (protein)
o Disorders: Polycythemia, Anemia
Some common forms of anemia are:
Pernicious –. Results from a lack of intrinsic factor from the stomach that helps
with the absorption of Vitamin B12.
 BIOS255 EXAM1 STUDY GUIDE
Introduction - General functions of cardiovascular System and composition of Blood

Different parts to centrifuged blood and what is in each part:
o Plasma – Upper layer- 55% (water, dissolved gasses, nutrients, waste products,
proteins)-
o Buffy Coat – middle layer- less than 1% (WBCs and Platelets)
o Hematocrit (Erythrocyte) – lowermost layer- 45% (RBC)
Three formed elements found in blood
o RBCs (Erythrocytes): 4.2 – 6.2 million/µL
o WBCs (Leukocytes): 5,000 – 10,000/µL
o Platelets: 130,000 – 360,000/µL
Blood Plasma
plasma makes up over half of blood volume. It is a complex mixture of water, nutrients,
hormones, electrolytes (like Na+, K+), gases, nitrogenous wastes (urea), and proteins.
Plasma proteins are mainly produced by liver and exert the greatest effect on the physical
characteristics of whole blood.
The major plasma proteins in blood include albumin, globulins, and fibrinogen.
Albumin constitutes 60% influences the viscosity and osmolarity of blood

Globulins make up 36% of plasma proteins, are antibodies secreted to combat
pathogens in specialized immune responses.

Fibrinogen constitutes about 4% of all plasma proteins. It is a soluble precursor
of another protein called fibrin.
blood plasma - fibrinogen = blood serum.

Introduction to Erythrocytes, their role, homeostasis, disorders, blood groups and clinical
significance

Red Blood Cells (RBCs) – lack a nucleus, biconcave disc shape, bags of hemoglobin,
carry oxygen and some carbon dioxide
Hct- hematocrit- % of whole blood occupied by RBC.
o Formed in the red bone marrow from the hematopoietic stem cell, myeloid stem
cell, erythroblast, reticulocyte, mature RBC
▪ To make an RBC you need: EPO or erythropoietin (released from kidney
due to low oxygen in the blood – hypoxemia); amino acids; iron (ferrin);
vitamin B12
▪ The steps to hemoglobin recycling: functions of bilirubin, biliverdin,
stercobilin, urobilinogen, and transferrin
▪ Hemoglobin is made up of iron (4 heme groups)- binds to oxygen and
globin (protein)
o Disorders: Polycythemia, Anemia
Some common forms of anemia are:
Pernicious –. Results from a lack of intrinsic factor from the stomach that helps
with the absorption of Vitamin B12.
 Iron deficiency – impaired hemoglobin production due to lack of iron.
Thalassemia – impaired synthesis of globin proteins.
Aplastic – reduced erythrocyte mitosis in red bone marrow.
Sickle-cell – hereditary hemoglobin defect that 'sickles' in low oxygen, causing
cells to lodge in small vessels and reduce blood flow.
Hemorrhagic – due to loss of blood.
Hemolytic – anything that causes the destruction of erythrocytes (e.g., blood
transfusion incompatibility, parasitic infections, drug reactions).

o ABO Blood Typing: Antigens versus Antibodies, blood type compatibilities

Blood type AB does not have any antibodies and thus can safely receive blood from A, B, AB,
and O blood types. This blood type is called the universal recipient. Blood type O does
not have any antigens on its RBCs and can donate blood to all other types. This blood type is
called the universal donor
Introduction to Leukocytes

Never Neutrophils 60% Microphages (phagocytic), bacterial infections
Let Lymphocytes 30% T and B-cells, mount immune response, cancer cells,
viruses
My Monocytes 8% Macrophages, phagocytize pathogens, dead
neutrophils, and debris of dead cells
Engine Eosinophils 3% Parasitic worms, phagocytize antigen-antibody
complexes, allergies, and inflammatory chemicals
Blow Basophils >1% Allergic reactions, secrete histamine, secrete heparin

Two categories of leukocytes
o Granulocyte: -phils; Neutrophils, Basophils, Eosinophils
o Agranulocytes: -cytes; Monocytes, Lymphocytes
Lymphoid stem cells: give rise to B-cell lymphocytes (PRODUCE ANTIBODIES), T-cell
lymphocytes, and Natural Killer cells
Myeloid stem cells: give rise to RBCs, platelet, Monocytes, Neutrophils, Eosinophils, and
Basophils
Introduction to Thrombocytes

Three steps to hemostasis
o Vascular spasm
o Platelet plug formation
o Coagulation
▪ Extrinsic pathway
▪ Intrinsic pathway
▪ Common pathway – Prothrombin (plasma protein) , thrombin (enzyme
converts Fibrinogen into Fibrin), and fibrin (insoluble sticky protein
that adheres to the walls of vessels)
There are two pathways to coagulation: intrinsic and extrinsic mechanisms.
The intrinsic mechanism is the reaction pathway that uses clotting factors that
are within the blood itself.
The extrinsic mechanism is initiated by clotting factors that are released by the
damaged blood vessel or nearby tissues.
Both pathways will eventually arrive to activate Factor X.

In the presence of Ca2+, factor X combines with factor III and produces the enzyme
prothrombin activator. This converts a plasma protein called prothrombin to thrombin.
Thrombin is an enzyme that will convert fibrinogen to fibrin.

Extrinsic or Intrinsic Pathway -→ Factor X -→Prothrombin activator →Thrombin
→Fibrinogen into Fibrin
 o Clot retraction
Clots are disposed of once tissue repair is completed with the help of protein plasmin. This
dissolution is known as fibrinolysis.
Anticoagulants: Heparin is a chemical secreted by basophils and mast cells, which blocks
thrombin from working on fibrinogen.
Understand Disorders: Hemophilia, Thrombosis, Embolus, Hematoma
Gross and Microscopic anatomy of the heart

Location and position of the heart
Pericardium: parietal pericardium and visceral pericardium (serous membrane that lines
the heart)
Layers to the Heart Wall: Epicardium (same is visceral pericardium), Myocardium
(contains cardiac muscle), and Endocardium
R and L Atrium, R and L Ventricle and the great vessels that attach to each. Left
ventricle the thickest since it sends blood against gravity to the brain.
Heart valves:
o AV valves- between atrium and ventricles- prevents backflow from ventricles into
atrium
▪ Tricuspid – right
▪ Bicuspid/Mitral – left
o Semilunar valves
▪ Pulmonic – right ventricle and pulmonary trunk
▪ Aortic – left ventricle and aorta
Surface anatomy and internal structures
Myocardial blood supply

Coronary circulation- ARTERIAL SUPPLY OF OXYGENATED BLOOD
Coronary Sinus- VENOUS DRAINAGE
Microscopic anatomy of the heart muscle – short, fat, branched, uninucleated, striated,
involuntary, intercalated disc
Cardiac Pacemaker Cells
The specific region of the heart responsible for setting the heart’s rhythm is known as the
sinoatrial node (SA). This region consists of specialized cardiomyocytes known as pacemaker
cells with membrane potential starting at -60mV. This depolarization results from a slow influx
of Na+.

Physiology of cardiac muscle contraction

Autorhythmic
Depolarize through leakage of potassium
Reaching threshold opens voltage-gated sodium channels, slow voltage calcium
channels, and voltage-gated potassium channels.

Blood flow through heart

Superior vena cava, Inferior vena cava, and Coronary sinus; Right atrium; Tricuspid
valve; Right ventricle; Pulmonary semilunar valve; Pulmonary trunk; Right and Left
Pulmonary Arteries; Lungs; Right and Left Pulmonary Veins; Left Atrium;
Bicuspid/Mitral valve; Left ventricle; Aortic valve; Aorta
Electrical conduction system of the heart and electrocardiogram

SA node, AV node (bundle), Bundle branches, Purkinje fibers
Electrocardiogram (ECG/EKG)

P wave – atrial depolarization
PQ interval – ventricular filling
QRS Complex – Ventricular depolarization
ST segment – ventricular emptying
T wave – ventricular repolarization

Cardiac cycle
 Systolic versus Diastolic
o Atrial Systole/Ventricular Diastole – AV valves OPEN, Semilunar valves
CLOSED
o Atrial Diastole/Ventricular Systole – AV valves CLOSED, Semilunar valves
OPEN
o Matching electrical conduction to heart systole vs diastole
o Pressure and volume relation. As volume goes up, pressure goes down. As
volume goes down, pressure goes up.
Cardiac cycle lasts from one p wave to the beginning of the next p wave.
Heart Sounds
This process of listening to sounds made by the body is called auscultation.
The typical “lub-dub” sound is a result of the closing of heart valves.
The first sound (S1 or “lub”) is caused by the closure of the atrioventricular valves during
ventricular contraction (systole).
The second sound (S2 or “dub”) is produced by closure of the aortic and pulmonary
semilunar valves during ventricular relaxation (diastole).

Regulation of Cardiac Output, Stroke Volume and Heart rate

CO = SV x HR
o Since cardiac output is affected by stroke volume (amount of blood leaving
the left ventricle per beat) and the heart rate (beats per minute) anything that
effects volume of blood or how fast or slow the heart beats will affect CO
SV = EDV – ESV
Factors Affecting Cardiac Output – HR, stroke volume (

Autonomic Innervation of the Heart
There are two cardiac centers in the medulla oblongata of the brainstem.
The cardioacceleratory center sends sympathetic signals by way of the cardiac nerves.
Stimulation by these nerves increases heart rate and contractility of the heart chambers.
 Parasympathetic signals from the cardioinhibitory center travel by way of the vagus
nerves. This results in slowing the rate of spontaneous depolarizations and leads to
decreased heart rate.