Hemodynamics, meaning literally "blood movement", is the study of
bloodflow or the circulation.
All animal cells require
oxygen(O2) for the conversion of carbohydrates, fats and proteins into carbon dioxide(CO2), water and energy in a process known as aerobic respiration. The circulatory system functions to transport the blood to deliver O2, nutrients and chemicals to the cells of the body to ensure their health and proper function, and to remove the cell wastes.
The circulatory system is a connected series of tubes, which includes the heart, the arteries, the micro-circulation, and the veins.
The heart is the driver of the circulatory system generating cardiac output (CO) by rhythmically contracting and relaxing. This creates changes in regional pressures, and, combined with a complex valvular system in the heart and the veins, ensures that the blood moves around the circulatory system in one direction. The “beating” of the heart generates pulsatile blood flow which is conducted into the arteries, across the micro-circulation and eventually, back via the venous system to the heart. The aorta, the main artery, leaves the left heart and proceeds to divide into smaller and smaller arteries until they become arterioles, and eventually capillaries, where oxygen transfer occurs. The capillaries connect to venules, into which the deoxygenated blood passes from the cells back into the blood, and the blood then travels back through the network of veins to the right heart. The micro-circulation, the arterioles, capillaries and venules, constitutes most of the area of the vascular system and is the site of the transfer of, O2, glucose and substrates into the cells. The venous system returns the de-oxygenated blood to the right heart where it is pumped into the lungs to become oxygenated and CO2 and other gaseous wastes exchanged and expelled during breathing. Blood then returns to the left side of the heart where it begins the process again. Clearly the heart, vessels and lungs are all actively involved in maintaining healthy cells and organs, and all influence hemodynamics.
The factors influencing hemodynamics are complex and extensive but include CO, circulating fluid volume, respiration, vascular diameter and resistance, and blood viscosity. Each of these may in turn be influenced by physiological factors, such as diet, exercise, disease, drugs or alcohol, obesity and excess weight.
Our understanding of hemodynamics depends on measuring the blood flow at different points in the circulation. A basic approach to understanding hemodynamics is by “feeling the pulse”. This gives simple information regarding the strength of the circulation via the systolic stroke and the heart rate, both important components of the circulation which may be altered in disease. The blood pressure can be simply measured using a plethysmograph or cuff connected to a pressure sensor (mercury or aneroid manometer). This is the most common clinical measure of circulation and provides a peak systolic pressure and a diastolic pressure, often quoted as a normal 115/75. Sometimes the mean arterial pressure is calculated.
MAP ~= ((BPdia*2)+BPsys)/3 mmHg (BPdia is counted twice since the heart spends two thirds of the heart beat cycle in the diastolic)
*BPdia = Diastolic blood pressure
*BPsys = Systolic blood pressure
The arterial pulse pressure can be measured by placing a tonometer or pressure sensor on the skin surface above an artery. This provides a continuous pressure trace or arterial pulse pressure waveform which reflects cardiovascular performance (Fig1). A non-invasive Doppler can also be used to measure blood flow at any point in the circulation, including within the heart, the CO, and can be converted to a pressure difference using the modified Bernoulli equation, P=4V2. An invasive manometer (pressure sensor) can be inserted into an artery on the end of a catheter to measure intra-arterial pulse pressures providing information on cardiovascular performance. Importantly all of these measures should be accompanied by a measure of CO so that the function of the heart and vessels can be distinguished. This allows for more effective understanding and treatment of the cardiovascular system.
The heart and the vascular beds are a dynamic and connected part of the circulatory system and combine to effect efficient transportation of the blood. Circulation is influenced by the resistance of the vascular bed against which the heart is pumping. For the right heart this is the pulmonary vascular bed, creating Pulmonary Vascular Resistance (PVR), while for the systemic circulation this is the systemic vascular bed, creating Systemic Vascular Resistance (SVR). The vessels actively change diameter under the influence of physiology or therapy, vasoconstrictors decrease vessel diameter and increase resistance, while vasodilators increase vessel diameter and decrease resistance. Put simply increasing resistance (narrowing the vessel) decreases CO, and conversely decreased resistance (widening the vessel) increases CO.
This can be explained mathematically:
By simplifying D'arcy's Law, we get the equation that
Flow = Pressure/Resistance
When applied to the circulatory system, we get:
CO = 80 x (MAP – RAP)/TPR
However, as MAP >> RAP, and RAP is approximately 0, this can be simplified to:
CO ~= 80 x MAP/TPRFor right heart CO ~= MAP/PVRFor left heart CO ~= MAP/SVR
Physiologists will often re-arrange this equation, making MAP the subject, to study the body's responses.80 x MAP ~= CO x TPR
* [http://www.learnhemodynamics.com Learn hemodynamics]
* [http://www.e-piv.com/links/ Educational Particle Image Velocimetry (e-PIV) - resources and demonstrations]
* Berne RM, Levy MN. Cardiovascular physiology. 7th Ed Mosby 1997
* Rowell LB. Human Cardiovascular Control. Oxford University press 1993
* Braunwald E (Editor). Heart Disease: A Textbook of Cardiovascular Medicine. 5th Ed. W.B.Saunders 1997
* Siderman S, Beyar R, Kleber AG. Cardiac Electrophysiology, Circulation and Transport. Kluwer Academic Publishers 1991
* [http://www.americanheart.org American Heart Association]
* Otto CM, Stoddard M, Waggoner A, Zoghbi WA. Recommendations for Quantification of Doppler Echocardiography: A Report from the Doppler Quantification Task Force of the Nomenclature and Standards Committee of the American Society of Echocardiography. J Am Soc Echocardiogr 2002;15:167-184
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Look at other dictionaries:
hemodynamics — [hē΄mō dī nam′iks] n. Physiol. the study of the flow of blood in the circulatory system hemodynamic adj … English World dictionary
hemodynamics — The study of the dynamics of the blood circulation. [hemo + G. dynamis, power] * * * he·mo·dy·nam·ics or chiefly Brit hae·mo·dy·nam·ics iks n pl but sing or pl in constr 1) a branch of physiology that deals with the circulation of the blood 2 a)… … Medical dictionary
hemodynamics — noun the branch of physiology that studies the circulation of the blood and the forces involved • Hypernyms: ↑physiology * * * “+ noun plural but singular or plural in construction Etymology: International Scientific Vocabulary hem + dynamics 1 … Useful english dictionary
hemodynamics — noun plural but singular or plural in construction Date: circa 1857 1. a branch of physiology that deals with the circulation of the blood 2. the forces or mechanisms involved in circulation … New Collegiate Dictionary
hemodynamics — hemodynamic, adj. /hee moh duy nam iks, hem oh /, n. (used with a sing. v.) the branch of physiology dealing with the forces involved in the circulation of the blood. [1855 60; HEMO + DYNAMICS] * * * … Universalium
hemodynamics — noun ˌhimoʊdaɪˈnæmɪks The circulation and movement of blood in the body, and the forces involved therein. Syn: hemorheology … Wiktionary
hemodynamics — n. branch of physiology which studies the forces that influence blood circulation … English contemporary dictionary
hemodynamics — he·mo·dynamics … English syllables
Cardiac output — (Q or or CO ) is the volume of blood being pumped by the heart, in particular by a left or right ventricle in the time interval of one minute. CO may be measured in many ways, for example dm3/min (1 dm3 equals 1000 cm3 or 1 litre). Q is… … Wikipedia
Impedance cardiography — (ICG) is a hemorheology technique of using sensors to detect the properties of the blood flow in the Thorax.IntroductionImpedance cardiography (ICG), also referred to as thoracic electrical bioimpedance (TEB) and electrical impedance… … Wikipedia