The cardiovascular system

The cardiovascular system (sometimes called the circulatory system) is practically the most vital part of the human body, without it humanity would’ve been extinct millennia ago. This system consists of the heart, blood vessels, and the veins and arteries that run through the entire human body. Responsible for transporting the nutrients, oxygen, hormones, and the cellular waste products all throughout the body, the cardiovascular system is fueled by the body’s hardest-working organ -the heart. Even at rest, the average human heart easily pumps over five liters of blood throughout the human body every minute. The heart is located just behind and slightly left of the breastbone, where the organs connection to the cardiovascular system keeps the human body alive. It is also the main key organ in the cardiovascular system.
The human heart receives commands from the body through the circulatory system, that tells it when to pump more or less blood depending on an individual’s needs. While people are exercising or terrified, the heart pumps even faster to increase the delivery of oxygen due to heightened emotion or activity. There are four chambers that enclose the heart with thick muscular walls. The bottom part of the organ is divided into two chambers called the left and right ventricles, which pump blood out of the heart and throughout the entire body. The interventricular septum is wall that divides the ventricles. The upper part of the heart consists of the other two chambers, called the right and left atria, which receive blood upon entering the heart. The left and right atria are separated from the ventricles by the atrioventricular valves a wall called the interatrial septum divides. These divides are separated by the tricuspid valve, while the mitral valve separates the left atrium and the left ventricle. Another two cardiac valves separate the ventricles and the large blood vessels that carry blood exiting the heart. This is the pulmonic valve, which separates the right ventricle from the pulmonary artery leading up to the lungs, and the aortic valve, which then separates the left ventricle from the aorta which is the body’s largest blood vessel. Arteries transport blood away from the heart. These are known as the thickest blood vessels, with muscular walls that need to contract to keep the blood moving away from the heart and through the body.
In the systemic circulation, oxygen-rich blood is pumped from the heart and into the aorta. The huge artery first curves up and back from the left ventricle, then it flows down in front of the spinal column into the abdomen. At the start of the aorta, two coronary arteries branch off and divide into a network of smaller arteries that administer oxygen and nourish the muscles of the heart. Contrary to the aorta, the pulmonary artery transports oxygen-poor blood. The pulmonary artery divides into left and right branches from the right ventricle, en route to the lungs where blood gains oxygen.
As arteries get farther from the heart, they begin to branch out into arterioles, which are smaller and less elastic than where they originate. Veins aren’t as muscular as arteries but they do carry blood back to the heart. They contain valves that are used to prevent blood from flowing backwards. Veins are less flexible and thinner than arteries, but they also have the same three layers as arteries do. The two largest veins are the inferior and superior vena cavae. The terms superior and inferior does not mean that one vein is better than the other vein, but that they are located above and below the heart. A network of tiny capillaries is what connects the arteries and veins. Although they are tiny, the capillaries are one of the most important parts of the cardiovascular system because through them, the nutrients and oxygen are delivered to the cells. In addition, the capillaries also remove waste products such as carbon dioxide.
Tissues in the cardiovascular system encompass arteries, the heart, pericardium, and veins. These tissues are handled by researchers for investigations in order to find better methods of diagnosing or remedying such disorders as congestive muscular dystrophy, heart failure, coronary artery disease, or cardiomyopathy. The major tissues of the system would be the muscle, nervous, epithelial, and connective tissues.
The epithelial tissue is a type of protective tissue that covers the entire human body. It is built from closely packed cells in one or more layers. The Epithelial tissue is found inside the body and is called endothelium. The tissue is usually positioned on top of a thin layer of connective tissue, which is called the “basement membrane.” In the cardiovascular system, epithelial tissue can be located in the structure of the veins, arteries, and capillaries, as it also protects and covers the heart. Epithelial cells are compacted tightly together, with little to none intercellular spaces and only a small amount of intercellular substance. Regardless of the type, epithelial tissue is usually separated from the underlying tissue by a thin sheet of connective tissue; basement membrane. The basement membrane provides structural support for the epithelium and also binds it to neighboring structures.
Muscle tissue is made up of muscle cells that are able to contract, whether it is involuntarily or on command. This tissue enables us to move our whole body, or just certain parts when we wish. Muscle tissue also creates involuntary movement inside our bodies in every organ system. The heart is considered the main organ of the circulatory system, and is considered a muscle, therefore is largely made up of muscle tissue. Such contractions may result in the movement of the whole body or a portion of it, which is if the muscles are attached to a movable part of the skeleton. If the muscle is located in the wall of a hollow organ, its contractions may cause the contents of the organ to move.
The main function of the nervous tissue is to react to stimuli and send impulses to various organs through the body. This type of tissue is made up a specialized type of cell called neurons. They cells are highly responsive which means that they react quickly to stimuli. The nerve cell fibers embedded in connective tissue makes up the nervous tissue. This tissue is detrimental to the cardiovascular system because it helps the brain to deliver messages to all of the components of the system. Without this tissue, the circulatory system would not function.
Connective tissue is sometimes referred to as the “glue” that holds the body together and is the most common and plentiful type of tissue in the entire human body. The connective tissue consists of widely spread cells and its job is to connect, support, or surround other tissues and organs. The connective tissue is what makes up the structure of not only the cardiovascular system, but all of the other organ systems as well. This tissue can be found in the walls of arteries, veins, and capillaries, and, of course, in the makeup of the heart.
The cardiovascular system works closely with other systems in our bodies. It supplies oxygen and nutrients to our bodies by working in rhythm with the respiratory system. Simultaneously, the cardiovascular system helps carry waste and carbon dioxide out of the body. Hormones are produced by the endocrine system and are also transported through the blood in the circulatory system. Hormones, as the body’s chemical messengers, transfer information and instructions from one set of cells to another. For example, one of the hormones that are produced by the heart helps control the kidneys’ release of salt from the body.
When red blood cells pass by the lungs, the carbon dioxide that they are carrying diffuses into the lungs and in return, some oxygen diffuses into the red blood cells. The red blood cells are then transported all throughout the body through the arteries and give nutrients to organs and tissues by using diffusion. Carbon dioxide from the organs and tissues diffuses into the red blood cells just as oxygen diffuses out of the red blood cells. The cells then carry the carbon dioxide back to the lungs where then diffusion occurs, and the cycle begins yet again. Red blood cells also contain a substance called hemoglobin. Hemoglobin are small molecules found within red blood cells that give the blood its rich red color. Red blood cells are first produced in the bone marrow and then released into the bloodstream once they have matured. The lifespan of the cells is about three or four months, once they have aged or become damaged they are subsequently removed from the bloodstream by the spleen. The most important job of the red blood cells is to transport oxygen and other nutrients to every of the part of the body and get rid of wastes in the body, such as carbon dioxide.
Blood doping is a performance enhancing process and is frowned upon in athletic competitions worldwide. It is when an athlete removes some of the blood from their body a few weeks prior to a large competition. During these weeks, their body replenishes the blood that they lost, and then just before the competition, they inject the blood back into their body, giving themselves an irregularly high level of red blood cells in the bloodstream. The more red blood cells mean more oxygen, which in turn gives the athlete a higher endurance, and more stamina. Blood doping is a very dangerous and unsanitary process that will result in immediate disqualification from competition due to the fact that it gives an individual an advantage over the other competitors.
The cardiovascular system is instrumental in the body’s ability to maintain homeostatic control of several internal conditions. Blood vessels help maintain a stable body temperature by manipulating the blood flow to the surface of the skin. Blood vessels near the skin’s surface open during times of overheating to allow hot blood to dump its heat into the body’s surroundings. When hypothermia occurs, these blood vessels constrict to keep blood flowing only to vital organs in the body’s core. Blood also helps balance the body’s pH balance due to the presence of bicarbonate ions that act as a buffer solution. Finally, the albumins in blood plasma help balance the osmotic concentration of the body’s cells by maintaining an isotonic environment.
Several functions of the cardiovascular system can control blood pressure. Autonomic nerve signals from the brain along with certain hormones affect the rate and strength of heart contractions. Greater contractile force and heart rate will lead to an increase in blood pressure, which can also affect blood pressure. Vasoconstriction decreases the diameter of an artery by contracting the smooth muscle in the arterial wall. The sympathetic division of the autonomic nervous system causes vasoconstriction, which leads to increases in blood pressure and decreases in blood flow in the constricted region. Vasodilation is the expansion of an artery as the smooth muscle in the arterial wall relaxes after the fight-or-flight response wears off or under the effect of certain hormones or chemicals in the blood. The volume of blood in the body also affects blood pressure. A higher volume of blood in the body will raise the blood pressure by increasing the amount of blood pumped by each heartbeat. Thicker and more viscous blood from clotting disorders will also raise blood pressure.
Hemostasis, the clotting of blood and formation of scabs, is managed by the platelets of the blood. Platelets normally remain inactive in the blood, that is until they reach damaged tissue or leak out of the blood vessels through a wound. Once they are active, platelets change into a spiny ball shape and become very sticky in order to latch on to damaged tissues. Then they release chemical clotting factors and begin to produce the protein fibrin to act as structure for the blood clot. After which they also begin sticking together to form a platelet plug. The platelet plug will serve as a temporary seal to keep blood in the vessel and keep foreign material out of the vessel until the cells of the blood vessel can repair the damage to the vessel wall.
The heart is a four-chambered ‘double pump,’ where each side (left and right) operates as a separate pump. The left and right sides of the heart are divided by a muscular wall of tissue known as the septum of the heart. The right side of the heart receives deoxygenated blood from the systemic veins and pumps it into the lungs for oxygenation. The left side of the heart receives oxygenated blood originating from the lungs and pumps it through the systemic arteries to the tissues of the body. Each heartbeat results in the simultaneous pumping of both sides of the heart, making the heart a very efficient pump. Thus making the cardiovascular system overall the most essential part of the body for a person to live.

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