2006/09/01
223. zenbakia
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Move, heart
Text created by automatic translator Elia and has not been subsequently revised by translators.
Elia Elhuyar
The continuous ideal movement is impossible, there is nothing that moves without consuming energy. Man has often dreamed of this idea, a constant movement: the perpetuum mobile. It is a dream, and the laws of Physics have made clear why, but it is lawful to have some uncertainty. Do all things follow the laws of Physics? Isn't the heart an example of the perpetuum mobile idea? The answer is negative, but it is not far away.
Move, heart
01/09/2006 | Roa Zubia, Guillermo | Elhuyar Zientzia Komunikazioa
(Photo: Archive)
The heart does not break or invalidate the laws of Physics because it needs a source of energy that is not exhausted to move constantly. And, like any other part of the body, it must oxidize carbohydrates and other biomolecules to work. And if in this way you get energy, you only contract and relax. From this point of view, it is like any other muscle, another of the more than six hundred that the human body has.
However, it is a special muscle. In fact, the movement makes the heart special. This movement is the dance of life, essential to survive and, in general, the sign of being alive. It is true that being alive and moving are two different things, but in the case of the heart it seems the same: to be alive the heart has to move and to be able to move has to be alive.
No stop. Not only when the brain commands, but also according to the desire of life, but continuously. Whether or not the body is asleep, whether or not conscious, the heart cannot stop. In fact, evolution has not left the movement of the heart in the hands of the brain. The heart moves by itself: the child should not learn how to move; the brain should not tell him to be running; it is not
thinking of the dance of the heart. Heart activity is too important to leave it in the hands of the brain. Breath yes, in some cases it can be interrupted because the brain indicates it, but the heart does not stop. It depends on chemical reactions. And thanks to it, the heart never stays.
The goal is, of course, to pump blood, which can be done by accumulating blood in a cavity and tightening that cavity to expel it forcefully. There is no other muscle that makes this movement. That is why it is a special muscle, physically special.
The way of blood
Not the whole heart contracts at once, in one movement, but in two steps and in parts. When one part contracts, another relaxes and the movement pushes blood inside and outside the heart. In fact, each hemorrhage passes through two cavities within the human heart: the atrium and ventricle (upper and lower, respectively). To pass through both, the heart pumps blood in two steps, first contracts the blood accumulated in the atria
to send it to the ventricle and then, closing the way back with a valve, contracts the lower part to empty the ventricle.
The heart is asked much: seventy pulsations per minute for seventy, eighty or one hundred years.
Archive
It is a constant movement, a crazy dance. And he has to dance at a fast pace: the human heart performs seventy beats in a minute, in a coordinated way, for seventy, eighty or one hundred years. Much is asked of the heart.
Of course, we have to make a lot of use of this work. And so it comes out, since the human heart is a double pump, a double pump or two bombs stuck together. In each beat he takes the blood from two places and pushes it to two at a time, without mixing both. Since the two pumps are stuck together, a single movement of the whole heart is needed to function, thus avoiding the loss of synchrony. And it is that both are launched in each beat by a single order.
Electric stirring
The order is an electric pulse, as the muscles are contracted by electrical impulses. And here's the key: the heart is constantly moving because chemical reactions cause constant electrical pulses.
These pulses are also not instantaneous. They spread very quickly through the tissue of the heart, but not suddenly. In fact, the time it takes for the pulse to spread throughout the heart is controlled by the heart itself, since electricity expands very quickly, causing a small delay in the pulse.
In this sense, you can compare the heart with a clock or, at least, you can say that it is an organ with a clock inside. It produces pulses often adequate and extends them at a certain speed through the organ, so experts ensure that the heart has natural pacemakers.
The natural marker not only controls the rate of electric pulse generation but also the speed of propagation through the heart. Before you create the pulse up, open it down, pick it up in the heart center and send it back, you usually wait a while. It interrupts the propagation of the electric pulse, otherwise the atria and ventricles would contract simultaneously.
This top-down controlled tour is the responsibility of different areas of the heart. Somehow, to do so, the heart is wired. In physiology, the electrical installation of the heart is called the conduction system. However, although the installation activity is the origin of the beats, the installation itself does not explain why continuous pulses occur, why the heart does not stop.
It can accelerate and slow the heart. This allows doctors to control the beat rate when there is a problem.
Archive
Game of ions
By means of the intermediate, the heart does not stay because some ions continually enter and leave in the cells of the nodes. Movement: some ions move so the heart can dance. The driving force is electricity, but the origin of electricity is movement, ions, and the consequence of electricity is also movement, heart.
In order for the heart to move constantly, the movements of the ions form a cycle. Ions come in and out of cells, that is movement, but it is not a movement that occurs simultaneously for all ions. Electricity has its origin in the electrical potential derived from the existence of different concentrations on the two sides of the membrane, due to the outer barrier of the cell, the membrane, the entrance and exit of some ions, according to the needs.
They are mainly potassium and sodium ions. When the membrane is relaxed there are many potassium ions inside the cell and many sodium ions outside. The distribution of electrical charges generated by this situation is measurable: It is an electrical potential of about 90 millivolt, which seems little, 130 times less than a normal battery, but taking into account the contribution of all cells, enough to move the heart.
The cycle starts when the membrane opens the sodium channels. Sodium penetrates the cell into a ramp and electrical potential is lost, not entirely, but it is enough for biochemists to call depolarization. At that time there is a lot of sodium and potassium inside the cell. Then the membrane opens the potassium channels and large amounts of potassium come out of the cell. Consequently, the electrical potential of the membrane is recovered, i.e. repolarized. There is a lot of potassium outside and a lot of sodium inside, just the opposite of the initial situation. Therefore, to close the cycle, a protein present in the membrane expels sodium ions and introduces potassium ions.
Heart, two sounds
(Photo: G. Roa)
By placing the ear against a person's chest, two strokes are heard for each heartbeat. Two beats, two sounds, two sounds. However, these two sounds do not come from the muscle dance itself, that is, they are not a contractile and relaxing movement. On the contrary, what is heard is the sound of intracardiac valves. Inside the heart, blood must travel one direction, always forward, so that the reverse is hampered by both valves. The valves close sound. The first noise occurs by the closure of the two valves that obstruct the exit of the ventricles and the second by the closure of the two separating valves of atria and ventricles.
Electrocardiogram
(Photo: Archive)
The electricity generated by the heart generates electric fields around the surface. They arrive less than 3 millivolt, but it is a measurable electric field. The signal can be collected with a galvanometer and draw the voltage variation over time. This is the electrocardiogram.
The electric pulse extends from top to bottom. In each place an incidence of potential is generated and the usual image we see in the electrocardiogram is generated by combining all the incidents.
(Photo: G. Roa)
The graph that is normally obtained is a consequence of the propagation of the electric pulse. The upper, lower pulse and the electrical response of the parts of the heart is the usual graph of the electrocardiogram.
Other hearts
The heart is a characteristic of animals, the other living beings have no heart. And not all animals have the real heart.
Fish have a very simple heart, with an atrium and a ventricle (A). Reptiles, on the other hand, have a three-cavity heart, consisting of two atria and a single ventricle (B). Oxygenated and non-oxygenated blood is mixed in this ventricle. Finally, birds and mammals have a four-cavity heart with two atria and two ventricles (C). In these hearts there is no mixture of blood.
(Photo: G. Roa)
All large animals do have hearts. In addition, the hearts of larger animals are similar to the human heart, since all mammals are equal: two atria, two ventricles and two totally separate hemorrhages. Yes, each mammal has a heart the size that corresponds to the blood that will pump. The heart of an elephant can be around 30 kilos and that of a sperm whale exceeds 110 kilos. These giant hearts perform approximately 30 pulses per minute. In fact, zoologists have found that the higher the animal, the lower the frequency of beats. The heart of birds is very appropriate to compare, since it has the same structure, with two atria and two separate ventricles, and makes the beat much more often: that of a sparrow about 500 pulses per minute, and that of a hummingbird can do 1,200.
The design of the reptile heart is different. Two atria do, but they only have a ventricle, which comes where the blood is confused. And there are simpler hearts, with one atrium and one ventricle, like fish.
Insects have the heart in the abdomen, it is a long bag. Instead of blood, this heart pumps a green liquid called hemolinfo.
(Photo: G. Roa)
Regardless of the design, all large animals have the heart. There are also many small ones, such as insects, that have a heart in the shape of a pouch in the abdomen, of a single inlet; when the muscles of the area open the pouch is introduced the hemolinfo (green liquid of the insects instead of the blood), and when they press the hemolinfa leaves to the aorta, the only circulation conduit that has the insect. It is a true heart, very simple, but real. It pumps the hemolinfo and that is why it is the heart.
The boundary between having and having no heart should be sought in small animals. The border is diffuse, sometimes the heart is only a simple esplanade of the circulatory tube. However, there are animals without heart, without circulatory systems or digestion channels. In this group there are many worms and among the most prestigious is tennis. It is a heartless animal.
Fast, slow
The heart itself produces the electrical pulses it needs. It has three zones, two nodules and a network of special cells. In the three predominates the sinoatrial nodule that produces between 60 and 100 beats per minute. The other two zones contribute to their expansion and, in case of problems, they can generate their own pulses with their own frequency. The atrioventricular nodule can cause 40 to 60 pulses and the Purkinje network can produce 20 to 40 pulses.
However, the heart is prepared to change the frequency of heartbeats based on the body's blood needs. The order must be created automatically regardless of the “desire” of the brain. To do this, the body has two nervous systems acting on the heart. One, the sympathetic system, forces the heart to accelerate and the other to stop the parasympathetic.
These mandates, in short, are small molecules; the sympathetic system uses adrenaline and noradrenaline to stimulate the heart and parasympathetic to slow down the heart of acetylcholine.
Roa Bridge, Guillermo
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