Overview of the cardiovascular syst

Overview of the cardiovascular system
In the simplest terms, a cardiovascular system is a series of tubes (the blood vessels) filled with fluid (blood) and connected to a pump (the heart).
Pressure generated in the heart propels blood through the system.
The blood picks up oxygen at the lungs and nutrients in the intestine and then delivers these substances to the body’s cells while simultaneously remove cellular waste and heat for excretion.

In addition, the cardiovascular system plays an important role in cell to-cell communication and in defending the body against foreign invaders.
The cardiovascular system transports materials throughout the body
The primary function of the cardiovascular system is the transport of materials to and from all parts of the body.
Substances transported by the cardiovascular system can be divided into (1) nutrients, water and gases that enter the body from the external environment, (2) materials that move from cell to cell within the body, and (3) waste that the cells eliminate

Cell to cell communication is a key function of the cardiovascular system.
For example, hormones, glucose and defense team.

The cardiovascular system consists of the heart, blood vessels and blood
The cardiovascular system is composed of the heart, the blood vessels and the cells and plasma of the blood.
Blood vessels that carry blood away from the heart are called arteries.
Blood vessels that return blood to the heart are called veins.

The heart is divided by a central wall or septum into left and right halves.
Each half functions as an independent pump that consists of an atrium (central room) and ventricle (ventriculus, belly)
The atrium receives blood returning to the heart from the blood vessels.
Ventricle pumps blood out into the blood vessels.

The right side of the heart receives blood from the tissues and send it to the lungs for oxygenation.
The left side of the heart receives newly oxygenated blood from the lungs and pumps it to tissues throughout the body.
In living people, well-oxygenated blood is bright red and low-oxygen blood is a darker red.
Under some conditions, low oxygen blood can impart a bluish color to certain areas of skin, such as around the mouth and under the fingernails. This condition, known as cyanosis (kyanos, dark blue).

Pressure, volume, flow and resistance
In physiology, we are concerned with how blood flows-in other words, with the mechanisms or forces that create blood flow.
A simple mechanistic answer to why does blood flow is that liquids and gases flow down pressure gradients (P) from regions of higher pressure to regions of lower pressure.
For this reason, blood can flow in the cardiovascular system only if one region develops higher pressure than other regions.

In humans, the heart creates high pressure when it contracts.
As blood moves through the system, pressure is lost because of friction between the fluid and the blood vessel walls.
The highest pressure in the vessels of the cardiovascular system is found in the aorta and systemic arteries.
The lowest pressure is in the venae cavae.

Resistance opposes flow
All movement creates friction.
Blood flowing through blood vessels encounters friction from the walls of the vessels and from cells within the blood rubbing against one another as they flow.

The tendency of the cardiovascular system to oppose blood flow is called the system’s resistance to flow.

The resistance to fluid flow offered by a tube increases as the length of the tube increases
Resistance increases as the viscosity of the fluid increase.
Resistance decreases as the tube’s radius increase.

As the radius of a tube decreases, the resistance to flow increases.


Cardiac muscle and the heart
- The heart is a muscular organ, about the size of a fist.
- It lies in the center of the thoracic cavity.
- The heart is encased in a tough membranous sac, the pericardium (peri, aroud + kardia, heart).
- A thin layer of clear pericardial fluid inside the pericardium lubricates the external surface of the heart as it beats within the sac.

Inflammation of the pericardium (pericarditis) may reduce this lubrication creating a sound known as a friction rub.
The heart itself is composed mostly of cardiac muscle or myocardium (myo, muscle = kardia, heart)

The major blood vessels all emerge from the base of the heart.
The aorta and pulmonary trunk (artery) direct blood from the heart to the tissues and lungs respectively.
The venae cavae and pulmonary veins return blood to the heart.

Heart valves ensure one-way flow in the heart
Blood flows through the heart in one direction.
Two set of heart valves ensure one way flow
- one set (the artrioventricular valves)
- second set (the semilunar valves)

Cardiac muscle cells contract without innervation
The bulk of the heart is composed of cardiac muscle cells or myocardium.
Most cardiac muscle is contractile but about 1% of the myocardial cells are specialized to generate action potentials spontaneously.
The signal for myocardial contraction comes not from the nervous system but from specialized myocardial cells known as autorhythmic cells or pacemakers.

The heart as a pump
Individual myocardial cells must depolarize and contract in coordinated fashion to create enough force to circulate the blood.
The depolarization begins in the sinoatrial node SA node) and spread rapidly through a specialized conduction system.

Pacemakers set the heart rate
The cells of SA node set the pace of the heart beat.
If this node is damaged and cannot function, one of the slower pacemakers in the heart takes over.

The electrocardiogram reflects electrical activity
Electrocardiograms (ECGs or EKGs-from the Greek word kardia, meaning heart) provide indirect information about heart function.
NaCl-based extracellular fluid are good conductors of electricity.
Walter Einthoven created “Einthoven’s triangle” a hypothetical triangle created around the heart when electrodes are placed on both arms and the left leg.

Einthoven’s triangle, ECG electrodes attached to both arms and the left leg form a triangle. Each two electrode pair constitutes one lead and only one lead is active at a time.

An ECG tracing shows the summed electrical potentials generated by all cells of heart.
Different component s of the ECG reflect depolarization or reprolarization. Of the atria and ventricle.
Depolarization initiates muscle contraction, these electrical events (waves) of an ECGs can be associated with contraction or relaxation (cardiac cycle).
There are 2 major components of ECGs, waves and segments.

Thee electrocardiogram. An electrocardiogram is divided into waves (P,Q,R,S and T), segment between the waves (the P-R and S-T segments), and intervals consisting of waves and segments such as the PR and QT interval. This ECGs tracing was recorded from lead I.

An ECGs provides information on heart rate and rhythm, conduction velocity and even the condition of tissues in the heart.

The heart contracts and relaxes during a cardiac cycle
Each cardiac cycle has 2 phrases; diastole, the time during which cardiac muscle relaxes and systole, the time during which the muscle is contracting (diastole, dilation; systole; contraction)

Stroke volume is the volume of blood pumped per contraction
Stroke volume is the amount of blood pumped by one ventricle during a contraction.
It is measured in milliliters per beat and can be calculated as follows:
volume of blood before contraction – volume of blood after contraction = stroke volume
For the average contraction in a person at rest:
135 mL – 65 mL = 70 mL (normal stroke volume)

Cardiac output is a measure of cardiac performance
How can we assess the effectiveness of the heart as a pump?
One way is to measure cardiac output (CO).
Cardiac output is an indicator of total blood flow through the body.
CO can be calculated by multiplying heart rate (beat per minute) by stroke volume (mL per beat or per contraction)
Cardiac output = heart rate  stroke volume

For an average resting heart rate of 72 beats per minute and a stroke volume of 70 mL per beat,
 CO = 72 beats/min  70 mL/beat
= 5040 mL/min (or 5L/min)

Heart rate is modulated by automatic neurons and catecholamines
An average resting heart rate in an adult is about 70 beats/minute (bpm).
The normal range is highly variable.
Heart rate is initiated by autorhythmic cells in the SA node , it is modulated by neural and hormonal input.

Blood flow and the control of blood Pressure
The blood vessels
The wall of the blood vessels are composed of layers of smooth muscle, elastic connective tissue and fibrous connective tissue.
The inner lining of all blood vessels is a thin layer of endothelium.
Endothelial cells secrete many paracrines and play important roles in the regulation of blood pressure, blood vessel growth and absorption of materials.

The smooth muscle of blood vessels is known as vascular smooth muscle.
Smooth muscle is arranged in either circular or spiral layers.
The aorta and major arteries are characterized by walls that are both stiff and springy.
Arteries have a thick smooth muscle layer and large amounts of elastic and fibrous connective tissue.
Capillaries are the smallest vessels in the cardiovascular system and lack of smooth muscle elastic or fibrous tissue.

- Capillaries are the site of exchange between the blood and the interstitial fluid.
- Blood flows from the capillaries into small vessels called venules.
- From venules, blood flows into veins that become larger in diameter as they travel toward the heart.
- Veins are more numerous than arteries and have a larger diameter.
- Veins lies closer to the surface of the body than arteries.

Angiogenesis create new blood vessels
- One topic of great interest to researchers is angiogenesis, the process that new blood vessels develop..
- The growth of malignant tumors is a disease state that requires angiogenesis.
- In contrast, corona