Cardiovascular Physiology Lecture Notes 01-03-2023 PDF

Summary

These notes cover the introduction and blood components of the cardiovascular system. They detail the vital functions of the system, including nutrient and waste transport, and highlight the importance of this system in maintaining homeostasis.

Full Transcript

1st Lesson

File name: (01)_Physiology _ DeVito_ 01-03-2023

Sbobinatore: Mehdi Najafipour Professor: Giuseppe De Vito
Revisore: Isabella Conti Date: 01/03/23

Introduction of the course:
This course will be held by professor De Vito and professor Blaauw that will cover the endocrine physiology.
The professors recommend attending the course in person, as there may be topics not covered in the course
material.
To be eligible to take the physiology exam, you must have passed the "The Human Body" and "The Building
Blocks" exams.
Lecture slides will be available on Moodle one day prior to each lecture.
The course will cover heart physiology, kidney physiology, digestive tract physiology and endocrine physiology
Professor’s contact for any questions:
E-mail: [email protected]
[email protected]
Tel.: 0498275223
Ufficio: Istituto di Fisiologia Umana, via Marzolo 3, first-floor room 19a.
Textbooks suggestions: Vander’s Human Physiology; Guyton and Hall Textbook of Medical Physiology; Ganong’s
Review of Medical Physiology; West‘s respiratory physiology. The essentials.
The professor highly recommends "West's Respiratory Physiology," a small book that he personally like. For those
who prefer video lessons, there are also some of professor West’s lessons available on YouTube.
https://youtube.com/playlist?list=PLE69608EC343F5691

CARDIOVASCULAR PHYSIOLOGY
Introduction, the general organization of the cardiovascular system and the blood

The first lesson will cover the introduction and blood, while the second lesson will focus on homeostasis and
coagulation. Coagulation is not only an important physiological process but also has significant implications for
therapy. In the medical field, you will encounter situations that require the use of anticoagulant or procoagulant
treatments, so it is important to become familiar with them.

Introduction
The cardiovascular system is a crucial system that starts developing early in life,
even during the embryonic stage. The heart of the embryo begins to beat only a few
weeks after conception. The heart’s early activation is vital for distributing
nutrients throughout the growing fetus. The development of the cardiovascular
system begins during the embryonic stage, with the heart being the first organ to
become functional. The heart’s early activation is necessary to provide organic substances and nutrients that
support the fetus’s growth and development. As the cardiovascular system develops, blood vessels and capillaries
form to distribute oxygen and nutrients to various parts of the body.

If we consider the activity of the heart, it is similar to that of the diaphragm muscles. The heart and the diaphragm
muscles play vital roles in the human body, and they are constantly active throughout life. The diaphragm muscle is
responsible for separating the abdominal cavity from the thoracic cavity, which is crucial for respiration. It is an
important muscle for studying the effects of activity on muscle degeneration as it never stops working, even during
sedentary activities such as watching television. Patients may undergo biopsies or electromyographic sessions to
assess diaphragm muscle activity in research studies.

Similarly, the heart is a vital muscle that beats approximately 3 billion times during an individual’s lifespan.
However, only 1% of heart cells are replaced per year, indicating a limited capacity for renewing heart muscles.
This limited capacity for replacement makes heart damage such as infarction, necrosis, and the death of human
muscle cells particularly severe, as the damage, cannot be fully repaired. The heart is therefore a critical organ that
requires proper care and attention to maintain its function throughout an individual’s lifetime.

Fundamental cardiovascular system functions:
The cardiovascular system is essential for various bodily functions, and it performs three main functions:
Transport of nutrients and removal of metabolic products:
The first and most essential function is the transportation of nutrients, specifically oxygen, glucose, liquids,
and proteins, to every cell in the body. The cardiovascular system accomplishes this task by circulating
blood throughout the body via the heart, arteries, veins, and capillaries. In addition to delivering necessary
nutrients, the cardiovascular system also facilitates the removal of metabolic waste, toxins, and
accumulated products from damaged or deceased cells, transporting them to be eliminated or repurposed
for future use.
Regulation of the total extracellular fluid:
Another vital function of the cardiovascular system is the regulation of the total extracellular fluid. French
physiologist Claude Bernard defined the concept of an internal environment, or “milieu intérieur,”1 as
essential for the evolution of the human body. This internal environment refers to the extracellular fluid,
where most of the metabolic and catabolic interactions in the body occur. Therefore, regulating the total
extracellular fluid is crucial for maintaining a stable internal environment. The cardiovascular system
achieves this through various mechanisms and it’s one of its main tasks.
Regulation of a wide variety of physiological functions, (transporting hormones, regulating body
temperature, etc.)

In addition to nutrient transportation and extracellular fluid regulation, the cardiovascular system also plays a
critical role in hormone transportation, which is essential for maintaining homeostasis. One significant function of
hormone transportation is thermoregulation, which regulates blood flow between the periphery and core of the
body. The regulation of blood flow is achieved through vasodilation and vasoconstriction in response to
environmental temperature changes.

During vasodilation, blood vessels in the periphery of the body dilate, allowing for the dissipation of heat and
exchange of heat or energy between the body and the environment. Conversely, during vasoconstriction, blood
vessels in the periphery of the body constrict, restricting blood flow and conserving heat when exposed to cold.
These processes are crucial for maintaining thermoregulation control in the body.

As homeothermic animals, humans operate within a large optimum range of temperature, typically between 34-38,
39, or 40 degrees Celsius. This range is necessary for the maximum catalytic activity of numerous enzymes that
operate in the human body. If the temperature falls outside of this range, the speed of chemical reactions in the
body will be reduced. In contrast, if the temperature is too high, it can lead to the denaturation of proteins, resulting
in severe health consequences.

1
NoS: check sbobina 1 of the 1st year’s physiology
NoP: During my academic career, I conducted extensive research on thermoregulation in Scotland, where we
focused on conducting experiments to understand this process.

The components of the cardiovascular system
Now we are going to say about the protagonists of these activities.

The Blood:
The first is blood, which can be subdivided into two main components:
plasma
cellular component
You can easily observe this separation by spinning the blood in a centrifuge.

The Heart:
Then we have the driving force of this system, a biological double pack: the heart. Double pack because it is
pushing the blood into two parallel circuits:
the systemic circulation
the pulmonary circulation

These two circuits share the same characteristic of maintaining a constant amount of blood per unit of time, which
is referred to as cardiac output. The cardiac output is the amount of blood ejected or pumped into the system per
minute and is approximately five liters per minute.

The right ventricle pumps blood into the pulmonary circulation, while the left ventricle pumps blood into systemic
circulation. However, the amount of blood pumped in both of them is 5Lit/min, the difference between these two
circuits lies in their pressure levels. The systemic circulation is a high-pressure circuit, while the pulmonary
circulation is a low-pressure circuit. This is an essential point that will be emphasized throughout this module.

Moreover, The heart is also divided into four chambers, including two superior atria and two inferior ventricles
separated by unidirectional valves. These valves ensure that the blood flows in one direction, preventing any
backward flow or regurgitation.

The Blood Vessels:
The other third protagonist of the cardiovascular system is the system of vessels, which can be divided into two
different categories:
Arteries:
Arteries are normally low resistant large diameter tubes, while arterioles are smaller and play an important role in
regulating total peripheral resistances.
Arterioles:
Arterioles are small in size yet play a vital role in regulating total peripheral resistances. By adjusting the caliber or
diameter of arterioles, the resistance to flow and volume of blood flow to different organs can be altered. This
alteration permits the modification of blood pressure and blood distribution to tissues according to their needs.

When the body is at rest, the muscles receive a constantly reduced amount of blood as they are not active.
However, when physical activity, such as walking, running, or other exercises, is initiated, the muscles become
activated, resulting in vasodilation of the arterioles. This vasodilation allows more blood to flow to the muscles.
Conversely, organs such as the kidneys or the gastrointestinal system, which do not require as much blood during
physical activity, receive less blood due to vasoconstriction. Therefore, arterioles play a crucial role in manipulating
the amount of blood going to specific organs according to their needs. Furthermore, arterioles are essential in
regulating blood pressure because they are the main site of resistance to flow.

In the upcoming lecture, we will delve into the physics of blood circulation and explore the role of arterioles in
regulating blood pressure and blood flow distribution in detail.

Capillaries
The capillaries, located between the arterioles and veins, are characterized by their short length, thin walls made up
of a single layer of cells, and slow blood flow. These structures are responsible for the exchange of oxygen and
carbon dioxide between the blood and tissues. Carbon dioxide produced by the tissues is absorbed by the blood,
while oxygen is transported from the blood to the tissues. However, it is important to note that this exchange of
gases is not uniform throughout the capillary system, and varies from the beginning to the end of the capillary
network. The short length and slow flow rate of the capillaries facilitate diffusion, which is a concentration-based
transport mechanism.
Venules
Veins
And then the venous and veins system is characterized by transport and reabsorption of blood towards the heart.
Normally, there is low resistance to flow and no pressure. But despite the absence of pressure, they can
accommodate the largest amount of blood. In each instant, most of the 5 liters of blood in our body is linked to the
venous system, which is very distensible. This concept is known as compliance: the relationship between volume
and pressure. The venous system can accommodate large volumes without raising the internal pressure. It is a
compliance system where a lot of fluid can be introduced without a great increase in pressure. Low compliance
means that a small amount of fluid inside will increase rigidity, sensitivity, and elasticity.

NoS: compliance is defined as a change in venous volume (ΔV) related to a change in distending pressure (ΔP,
compliance = ΔV/ΔP)

The decreased compliance of the vessels in aging, particularly the aorta, which becomes more sclerotic, is why
blood pressure measurement is an essential test for many elderly individuals during their visits to a general
physician (GP). Hypertension is a common issue among individuals over the age of 60, and blood pressure checks
are a critical indicator of the problem.

NoP: I'm almost 65. And so for the first time in two, three months ago I started taking some anti-hypertensive drug,
in a low condition. Because my systolic pressure is always 140, 145, 150. I'm an active person, but this is in respect
of aging, the vessels become sclerotic. So they are less disabled to accommodate the same amount of blood.

The Blood:
The blood is a vital liquid that is responsible for fulfilling many
needs of the body and is capable of reaching even the smallest parts
of our organs. It is composed of two main components, plasma and
cellular components. The yellowish part in this tube represents the
plasma, while the gray and red parts mostly comprise cells.
Additionally, there is a thin layer known as the buffy coat, which
primarily consists of a small portion of cells such as leukocytes
(white cells) and platelets.

Despite the bone marrow being predominantly responsible for
producing white cells, the cellular component of blood is mostly
composed of red cells. In fact, approximately 99% of blood cells are erythrocytes, commonly known as red cells.
This is a crucial fact to remember, as the main bulk of cells in the blood are red cells.

To separate the plasma and cellular parts of the blood, we can centrifuge it, as shown
in the image on the right. This process is routinely carried out in laboratories, as we
may need to store only the plasma after conducting experiments or analyzing
specific reactions. By centrifuging the blood, we can determine the proportion of
these two components, which is known as the hematocrit.

Hematocrit is a measure of the percentage of red blood cells in the blood. In general, the hematocrit of an average
adult ranges from 40 to 46%. Females tend to have an average hematocrit of 40-41%, while males have a slightly
higher hematocrit of 43-45%. Some individuals possess a genetically higher hematocrit of 50, 49, or 48%, which
can confer greater endurance sports proficiency.

Having a higher amount of red cells translates to having a higher concentration of hemoglobin, which is responsible
for transporting oxygen throughout the body. This can provide an advantage in endurance sports such as cycling,
marathons, and other similar activities. Individuals with a genetic predisposition towards a higher hematocrit level
have a greater ability to transport oxygen, which results in higher energy levels during these activities.

However, some individuals resort to doping to artificially increase their hematocrit levels to compensate for their
lack of natural ability. This will be further discussed during the lecture.

It is important to note that blood represents approximately 8% of the body mass in a 70kg man and typically ranges
from 5 to 5.5 liters in volume in all individuals. In contrast, a newborn baby weighing 3.2 kg would have a blood
volume of approximately 250 milliliters.

NoP: The average 70 kilos for men is something that comes across a lot. Men’s weight should be updated. This 70
kilos for men was probably established 50 years ago. Maybe now the average man is a bit bigger, and it would be
fair to include an average woman now, especially with gender equality

Plasma:

This table illustrates the components of the plasma:
Plasma, the yellowish liquid component of blood, is primarily composed of water, with 90% of its composition
being water. This makes up approximately 4% of the body mass, with the plasma volume in a typical man being
around 3 liters and in a typical woman being around 2.4 liters. Aside from its role in regulating temperature and
heat dissipation, plasma also contains a variety of organic and inorganic substances. In addition to water, it
containsions such as:

Calcium: important to regulate many functions.
Sodium: plays an important role as the main solute in the body.
Potassium: regulates plasma membrane, action potential, and gradient potential activities that occur within
the plasma

NoP: Remember that it was seen in the previous course the regulation of plasma membrane depolarization, action
potential. (check sbobina 2 of 1st year’s physiology)

Additionally, cholesterol, complex glycol, and other important parts of plasma include plasma proteins. The liver
is responsible for producing most of the plasma proteins, with albumin being the most important among them,
followed by immunoglobulins, which are also part of the plasma protein family. Plasma proteins are also involved
in coagulation and in transportation of iron, with fibrinogen and prothrombin playing a role in these processes.
Additionally, transferrin, a protein responsible for mediating the transport of iron, is also present in plasma.

Iron is an important mineral and it is twice as important as other ions. It is an essential component of hemoglobin,
and without it the production of hemoglobin is affected. Iron is a dynamic component that is continuously absorbed
and eliminated in the feces, hence a continuous supply of iron is necessary. Most of the iron present in the body is
not found in the blood; it is attached to transferrin and stored as ferritin. Therefore, when checking iron levels, it is
important to measure transferrin and ferritin levels in addition to blood iron levels.

Iron deficiency anemia is quite common, especially among young women who have a vegetarian diet that is not
properly balanced. It is possible to have a complete set of essential nutrients with a vegetarian diet, but it is
important to pay attention to iron intake. Iron is mostly contained in meat and fish, so vegetarians need to find
alternative sources. Transferrin, along with other proteins present in plasma, plays a crucial role in the
transportation of iron throughout the body, making it an essential component in maintaining iron levels.

Blood cells:

Now, at the main blood cells represented, we can distinguish between the erythrocytes on the left side and the
leukocytes or white cells in different subcategories, and then finally the platelets. Only the leukocytes are true
eukaryotes because they contain nuclei, while both the erythrocytes and platelets do not contain nuclei. A
eukaryotic cell is defined by containing a nucleus.
This table gives you an idea of the quantification of the total blood count, and if you do a blood analysis, you will
see the hematocrit and different counts of white cells, red cells and the volume of these cells. Sometimes you have
a total number but the volume is impaired or reduced, it can be an indication of a problem in blood manufacturing.

The upper image depicts the quantification of erythrocytes (NoS: eritrociti) and provides a range of normal values
on the right. Although the concept of a fixed internal environment proposed by Claude Bernard’s “milieu intérieur”
suggests stability, we know that there is always a range. Hemoglobin (NoS: emoglobina) is typically expressed in
g/l, and in this case, the hematocrit (NoS: ematocrito) is 48%, while MCV, MCH, MCHC, and RDW indicate the
volume and concentration of erythrocytes.

The white cells are divided into different categories, and there are ranges for each. For example, in the analysis
presented, all white cell counts are within normal range. However, during a seasonal allergy, it is common for
eosinophil counts to increase due to their involvement in allergic reactions. Similarly, infections may alter the white
cell counts, with bacterial infections often increasing neutrophil counts. Blood analysis serves as a benchmark for
immediate diagnosis, and while more sophisticated techniques have emerged, blood tests remain a fundamental tool
in medicine.

Hematopoietic stem cells (HSCs):
Blood cells are produced normally in adult life from the bone
marrow, starting from the so-called hematopoietic stem cells
(HSCs). The stem cells have the ability to differentiate into
various cell lines, giving rise to most of the cell lines. In this
image, you can observe that all of these cell lines originate
from the hematopoietic stem cell.
As said, this activity is done in the bone marrow, which
changes with age. Initially, during the first years of life, the
tibia, ribs, and vertebrae contain a lot of activity in the red bone
marrow, which is very active in producing cells. However, as
age progresses, these activities gradually decrease.
In the development of a fetus, blood cells are produced by the
liver and the spleen. While this hematopoietic activity is lost in
many cases throughout life, it can be reactivated under certain
circumstances. Damage, fibrosis, tumors, inflammation, and
exposure to radiation can all cause the bone marrow to lose its
ability to produce blood cells on its own, even in adults.
However, the spleen and liver can restart the production of
blood cells in these cases.
It is worth noting that 75% of cells in the bone marrow belong
to the line of white blood cells, while only 25% belong to red
blood cells. Despite this, red blood cells are the most abundant in the
blood.

Bone Marrow Transplant:

Bone marrow plays a crucial role in the treatment of certain blood disorders, such as tumors or leukemia, where a
transplant may be necessary. The bone marrow can be harvested from a donor through a puncture of a large bone
and injected into a patient in small amounts, which can stimulate the production of a large number of blood cells.

Hematopoietic stem cells are important cells that are derived from uncommitted totipotent stem cells that can
develop into different cell lines. However, these cells are scarce in number, even though they are abundant in the
blastocysts of embryos. This has led to a significant amount of research interest in the potential use of blastocysts
taken from embryos. However, ethical concerns have been raised regarding the use of embryos for this purpose.

Physiological versus Pathological Hematopoiesis:
Hematopoiesis in adults normally originates from the bone marrow, although in cases of damage, fibrosis, or
tumors, the spleen and liver can be reactivated, leading to a situation called pathological hematopoiesis. This is an
alternative to the traditional hematopoiesis starting from the bone marrow.

Red Blood Cells:

Red blood cells have a small biconcave shape with thicker edges and a flattening towards the
center, making them very flexible and ideal for diffusion of gases like oxygen and carbon
dioxide. This shape is much more efficient in gas exchange than a spherical shape. Being
flexible also allows the cell to squeeze through tiny vesicles, so instead of remaining circular,
they become more elongated. In this way, they can enter into very tiny capillaries of tiny
tubes, accommodate in the narrowest part of the
vascular tree.

The lifespan of the red cell is in avarage 120 days, four months,
approximately. In this period, a red cell can travel thousands of
kilometers, more than 1,000 kilometers.

The spleen operates an important role in this because it’s able to
accumulate the red cells, but also, acting as a filter for removing the
damaged cells, and in the spleen, there are macrophages, kupffer cells,
that can attack these damaged cells, destroying and eliminating the
damaged red cell.

Hemoglobin:

The red cells contain hemoglobin, that are going to be more detailed in the
respiratory physiology.
Normally typical adult hemoglobin in humans are structured by four subunits, two alpha and two beta subunits
(alpha2beta2). In the fetus hemoglobin, it’s different because we have two alpha and two gamma subunits
(alpha2gamma2). In this image on the right you can see the four subunits, two beta and two alpha. Not only
hemoglobin in adult is adult hemoglobin, there is a small amount of fetal hemoglobin, alpha2gamma2, two gamma
groups that remain, in some individuals.

Another important point about hemoglobin is that 2-3% of hemoglobin is so-called glycated hemoglobin. It’s a
molecule with an accumulation of glucose. But the importance of glycated hemoglobin is that its level is used as a
marker in the assessment of diabetes, especially in comparison to type 1, and type 2 diabetes. Normally, we have
2-3% of the total amount of glycated hemoglobin, but in a normal case, it’s okay. However, when it becomes 6, 7,
8%, it’s an indication of the gravity of the situation. The proportion of glycated hemoglobin decreases over time.
So, an elevation in the glycated hemoglobin in diabetes is an indication of the progression of the disease or poor
control.

Type 2 diabetes is very prevalent in our modern societies, in Italy, it’s about 6% of prevalence. In China, type 2
diabetes, in people over 60, it’s over 25% of the population. You have to consider that China is a country that is
evolving for 20 or 30 years, from a mostly rural, residing country to a machinic.

Hemoglobins are essential components of red blood cells that help in the transportation of oxygen throughout the
body. The capacity of hemoglobin to link with oxygen gives us an idea of its functionality. On average, men have
about 16 g/dL of hemoglobin, while women have 14 g/dL. When glycosylated hemoglobin is detected in a
70-kilogram man, it implies that approximately 900 grams of hemoglobin are present, with 0.3 grams being
destroyed while an equal amount is synthesized and released. This continuous balance is maintained through
activity and nutrition.

Mechanical Injuries:
The lifespan of a red blood cell is approximately 120 days. However, this can be altered by physical activity. If you
engage in activities such as walking or running for 10-15 kilometers a day, the lifespan of your red blood cells may
be affected. The red blood cells are very flexible and can move around the body through tiny tubes. In moderate
activities and rest 60-70 beats per
minute are normal and do not cause
alteration in red blood cells' lifespan.
However, high-intensity activities
such as those resulting in heart rates
of 130, 160, 190, or 200 bits per
minute can cause more damage to the
red blood cells, resulting in a faster
turnover.

The red blood cells can be also
damaged by heavyweight. For
example, soldiers who carry heavy
weights often experience damage to
their RBCs. Hematuria, the presence
of blood in urine, is a common
symptom seen in soldiers after a long
march or marathon, indicating
damage to RBCs and overflow of
vessels that results in blood appearing in the urine. Normal urine does not contain blood, and the presence of blood
indicates an overload of flow due to damaged RBCs.

Metabolic injuries:
Therefore, it is crucial to pay attention to nutritional requirements to support the production of RBCs.

Catabolism of Hemoglobin:
Hemoglobin is a critical component of RBCs, responsible for transporting oxygen
throughout the body. Hemoglobin is damaged as well as re-synthesized, and its
function is represented by the function of each subunit containing heme group. A
heme group is a typical group containing a porphyrin ring containing iron, which
is the point where oxygen links. Each hemoglobin contains four of these heme
groups, and when it is fully saturated with oxygen, it can carry four oxygen
molecules. Once the lifespan of hemoglobin is over, it is destroyed and undergoes a
series of reactions, releasing iron. The iron is partially reabsorbed, partially
attached to transferrin, partially stored as ferritin, and partially eliminated.

Hemoglobin is continuously manufactured in the human body; This fact has been established for over a century.
The primary driver for the production of erythrocytes and hemoglobin is a reduction in the amount of oxygen. Our
body possesses oxygen sensors that trigger the production of hemoglobin in response to low levels of oxygen in the
bloodstream. Erythrocytes have the crucial task of transporting oxygen to various parts of the body. To accomplish
this, they require a specialized program, which is stimulated by these oxygen sensors.

When red blood cells break down, the heme group, which is
the remaining part of hemoglobin, is transformed into
bilirubin. Bilirubin enters the liver and forms a part of the
bile, which plays a crucial role in the digestion of fat. This
highlights the significance of bilirubin in gastrointestinal
digestion. Once bilirubin enters the intestine, it is transformed
into stercobilin, which is excreted in the feces. Additionally, a
part of it is transformed into urobilin in the kidneys and
excreted in the urine.

It’s important to note that exposure to sunlight plays a key role
in the transformation of bilirubin into lumirubin, which is a
luminescent form of bilirubin. This is particularly relevant in
premature infants who may have developed moderate
yellowish coloration In Vitro. Exposure to UV light helps to
reduce the amount of total bilirubin in their system.
Determining the level of bilirubin through skin contamination
and facilitating the transformation of bilirubin to stercobilin
can also aid in reducing the amount of bilirubin.

NoS: It's important to note that exposure to UV light can convert bilirubin into a water-soluble molecule called
lumirubin, which can be excreted by the kidneys. This process is called photoisomerization and can be used as a
treatment for hyperbilirubinemia, including jaundice in premature infants.
Relationship between low oxygen pressure and the number of RBCs:

Paul Bert and Denis Jourdanet, two prominent French medical physiologists, were pioneers in establishing the
relationship between low oxygen pressure in the atmosphere and the number of red blood cells in animals and
humans. In their experiments, they exposed animals to high altitudes, where the atmospheric pressure and oxygen
levels are low. After a few weeks, they observed a significant increase in the number of erythrocytes in response to
this exposure.

Adaptation to hypoxia:

Athletes have long recognized the benefits of altitude training in preparing for competitive events. By living and
training at high altitudes, where oxygen levels are low, they stimulate erythropoiesis, leading to an increase in red
blood cell production and ultimately improving their oxygen-carrying capacity. This, in turn, can enhance
endurance and performance.

One example of a popular training destination for athletes is Sardinia, where elevations of 3,000 meters offer an
ideal setting for altitude training. The low oxygen levels at high altitudes limit the intensity of training, making it
more challenging for athletes to maintain their usual training regimen. However, by living at high altitudes and then
descending to lower altitudes to train, athletes can still challenge themselves and reap the benefits of altitude
training while minimizing the risk of overexertion.

The concept of “living high, training low” has been a popular strategy in exercise physiology for many years. It is
based on the principle that living at high altitudes stimulates erythropoiesis, while training at lower altitudes
allows athletes to maintain their usual intensity and training regimen. This approach has been found to be effective
in improving athletic performance and has been used by many elite athletes in preparation for major competitions.

In the United States and England, a significant study was conducted on the physiological response to adaptation to
low barometric pressure. The study was done on Spanish individuals in Colorado, which is a high-altitude place.
The results showed that there was a progressive increase in hemoglobin and red blood cells in response to living at
high altitudes for one month. This increase was due to the hormone erythropoietin (EPO), which is produced by
the kidney. The key factor that stimulates the
production of erythrocytes is the presence of EPO,
which is regulated by the hypoxia-inducible factors
(HIF). HIFs are a group of transcription regulators that
stimulate genes to produce other products in response to
hypoxia, discovered in recent decades by scientists
which led them to win a Nobel prize. However, EPO is
not entirely independent and is also under the influence
of other factors from which HIFs are amongst the most
important ones. While the kidneys are responsible for
the production of EPO in adult life, the liver produces it
in embryonic development and can reactivate its
production in response to hypoxia or stimulation by
drugs. It is essential to regulate the production of
erythrocytes since an excess amount of hemoglobin and
red blood cells can cause other problems.
The two lines in the image, are the hematocrit on the red line and the hemoglobin on the blue line.

When the body is exposed to hypoxia or a lack of oxygen, it is able to activate the production of erythropoietin
(EPO), which in turn facilitates the absorption of iron. Together, these processes aid in the production of
hemoglobin and red blood cells.

One of the key regulators of this process is the hypoxia-inducible factor (HIF). The HIF1 protein, for instance, is
able to stimulate thousands of target genes, among which are erythropoietin and vascular endothelial growth
factor (VEGF). This relationship between hypoxia and the production of EPO and VEGF is not only important for
understanding the body’s response to low oxygen levels but also has significant implications in the study of cancer
and its treatment. These markers are now being investigated as potential targets for cancer therapies.

Aside from their involvement in cancer treatment, these markers also play a role in the maintenance of muscle
mass. There are a lot of ongoing researches into how to block the growth of tumors by inhibiting vascular and
endothelial growth factors, which can reduce vascularization and therefore potentially slow the growth of tumors.
Conversely, these factors can also be used to stimulate muscle growth. However, there is a need to distinguish
between the potentially harmful effects of growth in cancerous tissue and the beneficial effects in healthy tissue.

Increasing vascularization and EPO levels also result in increased oxygen transportation in the body. Other factors
involved in this process include IGF-2, insulin, growth factors, inhibition of apoptosis, and metabolic
adaptation towards glycolytic enzymes. All of these factors are related to HIF-1 and contribute to the body’s
ability to adapt to hypoxia.

In addition to the importance of the sensors that regulate the production of EPO and other factors involved in the
body’s adaptation to hypoxia, it is also crucial to have sufficient levels of other constituents, such as iron and
sub-vitamins, to support the manufacture of red blood cells. Without these necessary components, anemia can
occur, which is a condition characterized by a reduction in hemoglobin content.

Polycythemia:

Conversely, an excess of red blood cells is known as polycythemia. There are two types of polycythemia: primary
and secondary.
Primary polycythemia (Polycythemia vera) is a tumor or tumor-like condition that stimulates excessive
production from the bone marrow. In this case, the red cell count in the blood can exceed 11 million per cubic
millimeter of blood, which is significantly higher than the normal range of 5-7 million.

Secondary polycythemia:, on the other hand, occurs as a result of an external factor such as hypoxia, chronic
obstructive pulmonary disease, or smoking. The increase in the number of red blood cells as a response to chronic
hypoxia is not a pathological condition, but rather a natural adaptation to the environmental stressor of low oxygen.
This adaptation is seen in populations that live at high altitudes, such as those living in Nepal or South America. In
these populations, the average erythrocyte count can be as high as 49% to 50% hematocrit, indicating a significant
increase in the number of red blood cells.

Note that 4000 meters is the limit of normal living condition, which leads to chronic polycythemia, above 5000
meters life is not easy to sustain. This increase in red blood cells is beneficial for individuals living in high-altitude
environments because it allows for increased oxygen-carrying capacity. This adaptation is also sought after by
athletes who train or live at high altitudes to improve their performance.

False polycythemia:, also known as relative polycythemia, is not caused by a true increase in the number of red
blood cells. Instead, it is caused by a reduction in the fluid plasma, such as dehydration, massive diarrhea, cholera,
or general infection. This condition results in thick and viscous blood, which reduces blood flow speed.

In the case of false polycythemia, In this panel, the red polycythemia and proportional red cells have the same red
bars, and what is changing is the limit of proportion.

The polycythemia linked to adaptation is the one that is beneficial, whereas the secondary one is caused by an
increase, not in the red cells, but in the fluid component, and it is more or less the same. Polycythemia caused by a
tumor is another condition to consider.

Blood Doping
Blood doping is the practice used to enhance the capacity of transforming oxygen. You can do this schematically in
three ways:

By doing blood transfusion, which involves taking half a liter of blood and injecting it into the circulation
of the person. In this case, you expand both the plasma and the cell.
By giving erythropoietin or other hormones similar to erythropoietin, which has the same effect.
By doing the hemotransfusion, which involves taking your blood, centrifuging it, storing it, and then
injecting it in the peripheral vein mostly red cells before the competition. In this way, you can expand in the
space of one day your hematocrit.
The use of performance-enhancing drugs in sports, commonly known as doping, is considered illegal. However,
during the 7th and 8th centuries, many athletes extensively used these drugs to boost their performance. Despite the
potential benefits, doping can pose serious health risks to athletes.

One of the major dangers of doping is the risk of infection. Athletes who use performance-enhancing drugs may
become more susceptible to infections due to the effects of the drugs on their immune systems. Additionally, the
use of needles for administering drugs increases the risk of bacterial and viral infections, such as hepatitis, if the
injection and blood manipulation is not performed in a sterile environment.

In normal circumstances, the proportion of cells in the blood is
well-balanced, resulting in a low viscosity that allows for easy
flow. However, artificially expanding the number of red blood
cells upsets this balance, increasing the cellular component and
viscosity of the blood. This can lead to slowed blood flow,
which makes it harder for the heart to pump and increases the
risk of thrombosis. If the hematocrit, is above 47-50%, the risk
of thrombosis is significant.

Recent news reports have revealed that some athletes are
competing with hematocrit levels as high as 57-60%. Such levels can be dangerous, as they upset the balance of
blood components, resulting in increased viscosity and a higher risk of health complications.

Having a hematocrit level of ~60% is comparable to having lentil soup instead of blood. This increased viscosity
can lead to a range of issues. In some cases, athletes have been known to sleep with a heart rate monitor set to 45 or
even 40 beats per minute, risking the development of bradycardia, as the viscosity of the blood is high it can lead to
other serious complications.

NoS: Bradycardia is a condition where the heart rate slows down to an abnormal level. When the heart rate drops
below a certain point, it can increase the risk of serious health problems such as thrombosis, infarction, or heart
attack. If an athlete’s blood is already viscous and slow-moving due to artificially elevated red blood cell levels, the
risk is even higher.

To prevent such health complications, athletes may cycle to reach a heart rate of around 67 before going back to
sleep. They may also use a tool on their arm that beeps when their heart rate drops below a certain level. This helps
them to monitor their heart rate and prevent it from dropping too low.

An increased hematocrit level can significantly increase the risk of ischemic events, such as abdominal infarctions.
While it is uncommon for athletes to experience such events, cases have been reported that raise suspicion of
doping.When an athlete who competes at a top level, such as a cross-country cyclist, is found to have an abdominal
infarction, the probability of doping is high, with estimates suggesting that it may be as high as 99%.

NoS: Abdominal infarctions occur when blood flow to the abdominal organs is blocked, leading to tissue damage
and potential organ failure.
In addition to the risks associated with doping, there are other factors that can impact blood circulation, including
viscosity. Viscosity is not just important for athletes but also for people at risk of developing an embolism or
thrombosis.

Individuals who have problems with their lower limb valves, which are not working correctly, may experience
blood stagnation, increasing their risk of developing vessel inflammation and embolism. This risk is especially high
during long flights, where prolonged periods of sitting can lead to reduced muscle contraction, limiting blood flow.
To combat this, individuals at risk are advised to stand up, move around, and contract their lower limb muscles to
pump blood and avoid stagnation. This advice is particularly important during long-haul flights lasting ten hours or
more.

Anemia:
We have factors controlling erythrocyte production, such as hypoxic-induced factors and erythropoietin. Anemia is
a common medical condition that can be caused by various factors. Some anemias are very common, such as
low-level anemia.
Anemia can be due to various reasons:
Deficiency of iron (iron-deficiency anemia): The most frequent one, vitamin B12, or folic acid. Vitamin
B12 is often associated with gastrointestinal problems. Some factors in the gastrointestinal system facilitate
absorption that might reflect as anemia.
Aplastic anemia: caused by damage to the bone marrow, the organ that manufactures the red cells, can
cause anemia. This can happen due to a tumor or toxic drugs.
Acute anemia is caused by massive loss of blood due to an injury (hemorrhage) or inadequate production
of erythrocytes due to damage to the kidney (renal anemia).
Hemolytic anemia: Another situation is when there is a genetic predisposition by which the erythrocytes
are more fragile, such as sickle cell disease, a well-known condition.

Abnormalities of Hemoglobin Production:
Anemia is associated with abnormalities in hemoglobin production. While there are hundreds of these conditions,
they can be divided into two main categories based on the type of abnormality:

Thalassemia: Was discovered in areas located near the Mediterranean coasts. The problem with
thalassemia is that the structure of hemoglobin is normal, but there is not enough production.
The second category is characterized by alterations in the structure of hemoglobin, as seen in sickle cell
anemia or sickle cell disorders. In this type of situation, the hemoglobin S (Hb-S) is altered while the
alpha chain remains normal. The beta chains have a
minor alteration, a single substitution of the amino
acid valine for glutamic acid, which results in the
production of hemoglobin S responsible for sickle
cell anemia. Sickle cell anemia is mostly inherited as
a heterozygous trait, where people tend to have only
one gene for the disease, and the normal
electrophoretic response is that there is a person with
a contaminated sickle cell trait. These individuals
normally do not have significant issues, but they can
experience fatigue when undergoing stress or
high-intensity exercise. When the disease is fully
 expressed, all the hemoglobin is altered, and the individual is homozygous for the disease.

Interestingly, in some populations in Africa, up to 40% of the people carry a genetic trait that provides resistance to
a common form of malaria. This has allowed the trait to be perpetuated over generations, as the resistance to
malaria provided by the genes is beneficial. Normally, genes of this kind tend to disappear over time, but the
maintenance of these genes in populations where malaria is prevalent has led
to protection from the disease.

Furthermore, the red blood cells in sickle cell anemia have a C-shaped,
sickle-like appearance, which is a deviation from the typical biconcave shape.
Although this shape makes the cell more resistant to pressure, it is more
fragile and less efficient, which leads to a tendency to break down
(hemolysis).

Blood Types:
As a doctor, it is crucial to understand the different blood types and their
associated antigens to avoid any risks during transfusions. While there are several antigens present on the surface of
red blood cells, the two main groups that are typically considered are the AB0 and RH groups.

AB0 :
The AB0 blood group system produces
antigens that can also be found in the
gastrointestinal system and can be induced by
food, for instance, the baby receives by
breastfeeding. Type A individuals have A
antigens on their red blood cells and
antibodies against B antigens in their plasma.
This means that they can receive blood from
either A or O types, but not from B or AB
types. If they were to receive incompatible
blood, it could trigger a dangerous reaction
with symptoms such as fever, pain, headache,
cardiovascular symptoms, and even death.

Conversely, type B individuals have B antigens on their red blood cells and antibodies against A antigens in their
plasma, making them unable to receive blood from A or AB types. Type AB individuals have both A and B
antigens on their red blood cells and no antibodies in their plasma, so they can receive any blood type. Type O
individuals have neither A nor B antigens on their red blood cells and have both anti-A and anti-B antibodies in
their plasma, making them able to receive only O-type blood.

To ensure safe transfusions, it is crucial to conduct a rapid test to determine a patient’s blood type and expose their
blood to different antigens to check for agglutination. Without this step, patients could be at risk for dangerous
reactions and potentially life-threatening situations. The lymphocytes will be agglutinated together, they will be
broken down, and there will be a very dramatic, potentially dangerous situation with fever, pain, headache,
cardiovascular symptoms, and even death.

RH group:
The Rh blood group system is a critical factor to consider in blood transfusions and pregnancies. The system was
named after the Rhesus macaque monkey in which this particular blood type was first discovered by scientists.
There are several antigens present in this system, including A, B, and D. However, the most significant is the D
antigen.

In situations where an Rh-negative person is exposed to Rh-positive blood, they produce anti-Rh antibodies. This
situation becomes particularly important in the case of erythroblastosis fetalis, which occurs during pregnancy. In
this condition, a mother who is Rh-negative carries a fetus that is Rh-positive. As a result, the mother’s body will
develop antibodies against the RH factor, but the first baby will not be affected.

The problem arises in the second pregnancy
if the baby is Rh-positive because the baby
will be exposed to the antibodies against the
Rh factor from the previous pregnancy,
which can lead to agglutination problems.
Hence, it is crucial to pay attention to the Rh
factor when providing transfusions and
during pregnancy. Even mixing up blood in
a small region of the placenta infusion can
lead to this type of response, which can be
potentially harmful.

Therefore, understanding and monitoring the
Rh group is crucial in managing blood
transfusions and ensuring the safety of the
fetus during pregnancy. The detection of Rh
factor incompatibilities is possible through
various diagnostic methods, including the
use of blood tests that check for Rh
antibodies.