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VASCULAR SYSTEM
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VASCULAR See also:SYSTEM . I. See also:ANATOMY.—The circulatory or See also:blood vascular apparatus consists of the central See also:pump or See also:heart, the See also:arteries leading from it to the tissues, the capillaries, through the walls of which the blood can give and receive substances to and from the tissues of the whole See also:body, and the See also:veins, which return the blood to the heart. As an See also:accessory to the venous system, the lymphatics, which open finally into the See also:great veins, help in returning some of the constituents of the blood. See also:Separate articles are devoted to the heart, arteries, veins and lymphatic system, and it only remains here to See also:deal with the capillaries. The blood capillaries See also:form a See also:close network of thin-walled tubules from z-h to of an See also:inch in See also:diameter, permeating, with a few exceptions, the whole of the body, and varying somewhat in the closeness of its meshwork in different 'parts. In the smallest capillaries, in which the arteries end and from which the veins begin, the walls are formed only of somewhat See also:oval endothelial cells, each containing an oval See also:nucleus and joined to its adjacent cells by a serrated edge, in the interstices of which is a small amount of intercellular See also:cement, easily demonstrated by staining the preparation with nitrate of See also:silver. Here and there the cement substance is more plentiful, and these spots when small are known as stigmata, when large as stomata. As the capillaries approach the arteries on the one See also:hand and the veins on the other they blend and become larger, and a delicate connective See also:tissue sheath outside the endothelium appears, so that the transition from the capillaries into the arterioles and venules is almost imperceptible; indeed, the difference between a large artery or vein and a capillary, apart from See also:size, is practically the amplification and differentiation of its connective tissue sheath. See also:Embryology.—The first See also:appearance of a vascular system is outside the body of the embryo in the See also:wall of the yolk See also:sac, that is to say, in the mesoderm or the See also:middle one of the three embryonic layers. The See also:process is a very See also:early one and in the chick is seen to begin at the end of the first See also:day of See also:incubation. The first occurrence . is a network made up of solid cords of cells forming in certain places solid See also:cell masses called the blood islands of Pander.' The central cells of these islands See also:divide by karyokinesis and gradually See also:float away into the vessels which are now being formed by fluid from the exterior, finding its way into the centre of the, cell cords and pressing the peripheral cells See also:flat to form the endothelial lining. These See also:free cells from the blood islands are known as erythroblasts and are the See also:primitive corpuscles of the foetal blood. They have a large reticular nucleus and at first are colourless though haemoglobin gradually develops within them and the blood becomes red (see BLOOD). The erythroblasts continue to multiply by karyokinesis in early foetal See also:life, especially in the See also:liver, See also:spleen, See also:bone marrow and lymphatic glands, though later on their formation only occurs in the red bone marrow. In most of the erythroblasts the nucleus soon becomes contracted, and the cell is then known as a normoblast, while ultimately the See also:general view is that the nucleus disappears by extrusion from the cell and the non-nucleated red blood plates or erythrocytes remain. The leucocytes or See also: P.) II. HISTORY OF See also:DISCOVERY See also:Galen, following Erasistratus (ob. 280 B.C.) and See also:Aristotle, clearly distinguished arteries from veins, and was the first to overthrow the old theory of Erasistratus that the arteries contained See also:air. According to him, the vein Galen. arose from the liver in two great trunks, the versa porta and vena cava. The first was formed by the See also:union of all the abdominal veins, which absorbed the chyle prepared in the See also:stomach and intestines, and carried it to the liver, wher it was converted into blood. The vena cava arose in the liver, divided into two branches, one ascending through the See also:diaphragm to the heart, furnishing the proper veins of this See also:organ; there it received the vena azygos, and entered the right ventricle, along with a large See also:trunk from the lungs, evidently the pulmonary artery. The vena azygos was the See also:superior vena cava, the great vein which carries the venous blood from the head and upper extremities into the right See also:auricle. The descending See also:branch of the great trunk supposed to originate in the liver was the inferior vena cava, below the junction of the hepatic vein. The arteries arose from the See also:left side of the heart by two trunks, one having thin walls (the pulmonary veins), the other having thick walls (the aorta). The first was supposed to carry blood to the lungs, and the second to carry blood to the body. The heart consisted of two ventricles, communicating by pores in the septum; the lungs were parenchymatous See also:organs communicating with the heart by the pulmonary veins. The blood-making organ, the liver, separates from the blood subtle vapours, the natural See also:spirits, which, carried to the heart, mix with the air introduced by respiration, and thus form the vital spirits; these, in turn carried to the See also:brain, are elaborated into See also:animal spirits, which are distributed to all parts of the body by the nerves.' Such were the views of Galen, taught until early in the 16th See also:century. Jacobus See also:Berengarius of See also:Carpi (ob. 1530) investigated the stricture of the valves of the heart. Andreas Vesale or Vesalius (1514–1564) contributed largely to anatomical know- Vesalius. ledge, especially to the anatomy of the circulatory organs. He determined the position of the heart in the See also:chest; 1 See Burggraeve's Histoire de l'anatomie (See also:Paris, 188o) he studied its structure, pointing out the fibrous rings at the bases of the ventricles; he showed that its wall consists of layers of See also:fibres connected with the fibrous rings; and he de-scribed these layers as being of three kinds—straight or See also:vertical, oblique, and circular or transverse. From the disposition of the fibres he reasoned as to the mechanism of the contraction and relaxation of the heart. He supposed that the relaxation, or diastole, was accounted for ,principally by the See also:longitudinal fibres contracting so as to draw the See also:apex towards the See also:base, and thus cause the sides to bulge out; whilst the contraction, or systole, was due to contraction of the transverse or oblique fibres. He showed that the pores of Galen, in the septum between the ventricles, did not exist, so that there could be no communication between the right and left sides of the heart, except by the pulmonary circulation. He also investigated minutely the See also:internal structure of the heart, describing the valves, the columnae corneae and the musculi papillares. He described the mechanism of the valves with much accuracy. He had, however, no conception either of a systemic or of a pulmonary circulation. To him the heart was a See also:reservoir from which the blood ebbed and flowed, and there were two kinds of blood, arterial and venous, having different circulations and serving. different purposes in the body. Vesalius was not only a great anatomist: he was a great teacher; and his pupils carried on the See also:work in the spirit of their See also:master. Prominent among them was See also:Gabriel See also:Fallopius (1523-1562), who studied the anastomoses of the blood vessels, without the See also:art of injection, which was invented by See also:Frederick Ruysch (1638-1731) more than a century later. Another See also:pupil was See also:Columbus Columbus. (Matthieu Reald Columbo, ob. 156o), first a prosector in the anatomical rooms of Vesalius and afterwards his successor in the See also:chair of anatomy in See also:Padua; his name has been mentioned as that of one who anticipated See also:Harvey in the discovery of the circulation of the blood. A study of his writings clearly shows that he had no true knowledge of the circulation, but only a glimpse of how the blood passed from the right to the left side of the heart. In his work there is evidently a See also:sketch of the pulmonary circulation, although it is clear that he did not understand the mechanism of the valves, as Vesalius did. As regards the' systemic circulation, there is the notion simply of an oscillation of the blood from the heart to the body and from the body to the heart. Further, he up-holds the view of Galen, that all the veins originate in the liver; and he even denies the See also:muscular structure of the heart.' See also:Servetus. In 1553 See also:Michael Servetus (1511-1553), a pupil or junior See also:fellow-student of Vesalius, in his Christianismi Restilutio, described accurately the pulmonary circulation.2 Servetus perceived the course of the circulation from the right to the left side of the heart through the lungs, and he' also recognized that the See also:change from venous into arterial blood took See also:place in the lungs and not in the left ventricle. Not so much the recognition of the pulmonary circulation, as that had been made previously by Columbus, but the discovery of the re- spiratory changes in the lungs constitutes Servetus's claim to be a See also:pioneer in physiological See also:science. See also:Andrea Cesalpino (1519-1603), a great naturalist of this See also:period, also made important contributions. towards the dis- Cesalptno. covery of the circulation, and in See also:Italy he is regarded as the real discoverer a Cesalpino knew the pul- monary circulation. Further, he was the first to use the ' An interesting See also:account of the views of the precursors of Harvey will be found in See also:Willis's edition of the See also:Works of Harvey, published by the See also:Sydenham Society. Compare also P. See also:Flourens, Histosre de la decouverte de la circulation du sang (Paris, .1854), and See also:Professor R. See also:Owen, Experimental See also:Physiology, its Benefits to Mankind, with an Address on Unveiling' the Statue of W. Harvey, at See also:Folkestone, 6th See also:August 1881. ' See Willis, Servetus and See also:Calvin (London, 1877). ' A learned and See also:critical See also:series of articles by See also:Sampson Gamgee in the See also:Lancet, in 1876, gives an excellent account of the controversy as to whether Cesalpino or Harvey was the true discoverer of the circulation; see also the Harveian oration for 1882 by See also:George See also:Johnston (Lancet, See also:July 1882), and Professor G. M. See also:Humphry, Journ. Anat. and Phys., See also:October 1882.See also:term "circulation," and he went far to demonstrate the systemic circulation. He experimentally proved that, when a vein is tied, it fills below and not above the ligature. The following passage from his Quaestiones Medicae (See also:lib. v. cap. 4, fol. 125), quoted by Gamgee, shows his views:
" The lungs, therefore, See also:drawing the warm blood from the right ventricle of the heart through a vein like an artery, and returning it by See also:anastomosis to the venal artery (pulmonary vein), which tends towards the left ventricle of the heart, and air, being in the meantime transmitted through the channels of the aspera arteria (trachea and bronchial tubes), which are extended near the venal artery, yet not communicating with the See also:aperture as Galen thought, tempers with a See also:touch only. This circulation of the blood (huic sanguinis circulations) from the right ventricle of the heart through the lungs into the left ventricle of the same exactly agrees with what appears from See also:dissection. For there are two receptacles ending in the right ventricle and two in the left. But of the two only one intromits; the other lets out, the membranes (valves) being constituted accordingly."
Still Cesalpino clung to the old See also:idea of there being an efflux and reflux of blood to and from the heart, and he had confused notions as to the veins conveying nutritive See also:matter, whilst the arteries carried the vital spirits to the tissues. He does not even appear to have thought of the heart as a See also:con-tractive and propulsive organ, and attributed the See also:dilatation to " an effervescence of the spirit," whilst the contraction—or, as he termed it, the " collapse "—was due to the See also:appropriation by the heart of nutritive matter. Whilst he imagined a communication between the termination of the arteries and the commencement of the veins, he does not appear to have thought of a See also:direct flow of blood from the one to the other. Thus he cannot be regarded as the true discoverer of the circulation of the blood. More recently Ercolani has Dls-
put forward claims on behalf of Carlo Ruini as being co very the true discoverer. Ruini published the first edition of circa-of his anatomical writings in 1598, the See also:year See also: 1530-1589), whose name is associated with the fibro-cartilaginous thickenings on the free edge of the semilunar valves (corpora Arantii). Hieronymus See also:Fabricius of Acquapendente (1537-1619), the immediate predecessor and teacher of Harvey, made the important step of describing the valves in the veins; but he thought they had a subsidiary See also:office in connexion with the See also:collateral circulation, supposing that they diverted the blood into branches near the valves; 'thus he missed seeing the importance of the anatomical and experimental facts gathered by himself. At the See also:time when Harvey arose the general notions as to the circulation may be briefly summed up as follows: the blood ebbed and flowed to. and from the heart in the arteries and veins; from the right side at least a portion of it, passed to the left side through ' the vessels in the lungs, where it was mixed with air; and, lastly, there were two kinds of blood—the venous, formed originally in the liver, and thence passing to the heart, from which it went out to the periphery by the veins and returned by those to the heart; and the arterial, containing " spirits " produced by the mixing of the blood and the air in the. lungs—sent out from the heart to the body and returning to the heart,by the same vessels. The pulmonary circulation was understood so far, but its relation to the systemic circulation was unknown. The See also:action of the heart, also, as a propulsive organ was not recognized. It was not until 1628 that Harvey }tarvey. announced his views to the See also:world by See also:publishing his See also:treatise De Motu Gordis et Sanguinis. His conclusions are given in the following celebrated passage: " And now I may be allowed to give in brief my view of the circulation of the blood, and to propose it for general See also:adoption. Since all things, both See also:argument and ocular demonstration, show that the blood passes through the lungs and heart by the auricles and 4 Gamgee, "Third See also:Historical Fragment," in Lancet, 1876. ventricles, and is sent for See also:distribution to all parts of the body, where it makes its way into the veins and pores of the flesh, and then flows by the veins from the circumference on every side to the centre, from lesser to the greater veins, and is by them finally discharged into the vena cava and right auricle of the heart, and this in such a quantity, or in such a See also:flux and reflux, thither by the arteries, hither by the veins, as cannot possibly be supplied by the ingestor, and is much greater than can be required for See also:mere purposes of See also:nutrition, it is absolutely necessary to conclude that the blood in the animal body is impelled in a circle, and is in a See also:state of ceaseless See also:motion, that this is the See also:act or See also:function which the heart performs by means of its See also:pulse, and that it is the See also:sole and only end of the motion and contraction of the heart " (bk. x. ch. xiv. p. 68). Opposed to Caspar See also:Hofmann of See also:Nuremberg (1571-1623), Veslingius (Vesling) of Padua (1598-1649), and J. Riolanus the younger, this new theory was supported by See also:Roger See also:Drake, a See also:young Englishman, who See also:chose it for the subject of a See also:graduation thesis at See also:Leiden in 1637, by See also:Werner Rolfinck of See also:Jena (1599-1673), and especially by See also:Descartes, and quickly gained the ascendant; and its author had the See also:satisfaction of seeing it confirmed by the discovery of the capillary circulation, and uni-Capillary versally adopted. The circulation in the capillaries
circula- between the arteries and the veins was discovered by
See also:don. See also:Marcellus See also:Malpighi (1628-1694) of See also:Bologna in 1661. He saw it first in the lungs and the mesentery of a See also:frog, and the discovery was announced in the second of two letters, Epistola de Pulmonibus, addressed to See also:Borelli, and dated 1661.1 Malpighi actually showed the capillary circulation to the astonished eyes of Harvey. See also:Anthony See also:van See also:Leeuwenhoek (1632-1723) in 1673 repeated Malpighi's observations, and studied the capillary circulation in a See also:bat's wing, the tail of a See also:tadpole and the tail of a See also:fish. William See also:Molyneux studied the circulation in the lungs of a See also:water See also:newt in 1683.E
The idea that the same blood was propelled through the body in a See also:circuit suggested that life might be sustained by renewing See also:Transfer the blood in the event of some of it being lost. About
of blood.
166o Lower, a London physician (died 1691), succeeded
in transferring the blood of one animal directly from its blood vessels into those of another animal. This was first done by passing a " See also:quill " or a " small crooked See also:pipe of silver or See also:brass " from the See also:carotid artery of one See also:dog to the jugular vein of another? This experiment was repeated and modified by See also:Sir See also:Edmund See also: In his De Motu Animalium (168o-85) he stated his theory of the circulation in eighty propositions, and in prop. lxxiii., See also:founding on a supposed relation between the bulk and the strength of muscular fibre as found in the ventricles, erroneously concluded that the force of the heart was equal to the pressure of a See also:weight of 18o,000 lb. He also recognized and figured the See also:spiral arrangement of fibres in the ventricles. The question was further investigated by See also: 226.per See also:minute. Then, allowing for the resistance of the vessels, he showed that the velocity diminishes towards the smaller vessels, and arrived at the amazing conclusion that in the smallest vessels it travels at the See also:rate of 4 in. in 278 days,—a See also:good example of the extravagant errors made by the mathematical physiologists of the period. Keill further described the See also:hydraulic phenomena of the circulation in papers communicated to the Royal Society and collected in his Essays on Several Parts of the Animal Oeconomy (1717). In these essays, by estimating the quantity of blood thrown out of the heart by each contraction, and the diameter of the aortic orifice, he calculated the velocity of the blood. He stated (pp. 84, 87) that the blood sent into the aorta with each contraction would form a See also:cylinder 8 in. (2 oz.) in length and be driven along with a velocity of 156 ft. per minute. Estimating then the resistances to be overcome in the vessels, he found the force of the heart to be " little above 16 oz.," —a remarkable difference from the computation of Borelli. Keill's method was ingenious, and is of historical See also:interest as being the first See also:attempt to obtain quantitative results; but it failed to obtain true results, because the data on which he based his calculations were inaccurate. These calculations attracted the attention not only of the anatomico-physiologists, such as See also:Haller, but also of some of the physicists of the time, notably of Jurin and D. See also:Bernoulli. Jurin (died 1750) gave the force of the left ventricle at q lb i oz., and that of the right ventricle at 6 lb 3 oz. He also stated with remarkable clearness, considering that he reasoned on the subject as a physicist, without depending on experimental data gathered by himself, the See also:influence on the pulse induced by See also:variations in the See also:power of the heart or in the resistance to be overcome.5 The experimental investigation of the problem was supplied See also:Bates. by See also:Stephen See also:Hales (1677-1761), See also:rector of See also:Teddington in
See also:Middlesex, who in 1708 devised the method of estimating the force of the heart by inserting a See also:tube into a large artery and observing the height to which the blood was impelled into it. Hales is the true founder of the See also:modern experimental method in physiology. He observed in a See also:horse that the blood See also:rose in the vertical tube, which he had connected with the crural artery, to the height of 8 ft. 3 in. perpendicular above the level of the left ventricle of the heart. But it did not attain its full height at once: it rushed up about See also:half-way in an instant, and after-wards gradually at each pulse 12, 8, 6, 4, 2, and sometimes. i in. When it was at its full height, it would rise and fall at and after each pulse 2, 3 or 4 in.; and sometimes it would fall 12 or 14 in., and have there for a time the same vibrations up and down at and after each pulse as it had when it was at its full height, to which it would rise again after See also:forty or fifty pulses .° He then estimated the capacity, of the left ventricle by a method of employing waxen casts, and, after many such experiments and measurements in the horse, ox, sheep, See also:fallow See also:deer and dog, he calculated that the force of the left ventricle in man is about equal to that of a See also:column of blood 71 ft. high, weighing 511 lb, or, in other words, that the pressure the left ventricle has to overcome is equal to the pressure of that weight. When we contrast the enormous estimate of Borelli (18o,000 lb) with the under-estimate of Keill (16 oz.), and when we know that the estimate of Stephen Hales (1677-1761), as corroborated by See also:recent investigations by means of elaborate scientific appliances, is very near the truth, we recognize the far higher service rendered to science by careful and judicious experiment than by speculations, however ingenious. With the exception of some calculations by See also:Dan Bernoulli (1700-1782) in 1748, there was no great contribution to haemadynamics till 18o8, when two remarkable papers ap-
peared from Thomas Young (1773-1829). In the first,
om= entitled " Hydraulic Investigations," which appeared You
in the Phil. Trans., he investigated the See also:friction and dis-
See also:charge of fluids See also:running in pipes and the velocity of See also:rivers, the
5 See also: 223. See also for an account of the criticisms of D. Bernoulli the See also:elder and others, Hailer's Elementa Physialogiae, vol. i. p. 448. " Hales, Statical Essays, containing Haemastatics, &c. (1733), vol. ii. p. I. resistance occasioned by flexures in pipes and rivers, the See also:propagation of an impulse through an elastic tube, and some of the phenomena of pulsations. This See also:paper was preparatory to the second, " On the Functions of the Heart and Arteries,"—the Croonian lecture for ,8o8—in which he showed more clearly than had hitherto been done (I) that the blood pressure gradually diminishes from the heart to the periphery; (2) that the velocity of the blood becomes less as it passes from the greater to the smaller vessels; (3) that the resistance is chiefly in the smaller vessels, and that the See also:elasticity of the coats of the great arteries comes into See also:play in overcoming this resistance in the See also:interval between systoles; and (4) that the contractile coats do not act as propulsive agents, but assist in regulating the distribution of blood.' The next See also:epoch of physiological investigation is characterized by the introduction :of See also:instruments for accurate measurement, use of and the graphic method of registering phenomena, maim- now so largely used in science.2 In 1825 appeared ments. E. and Wilhelm See also:Weber's (18(4–1891) Wellenlehre, and in 1838 Ernest Weber's (1795–1878) Ad Notat. See also:Ana-tom. et Physiolog. i., both of which contain .an exposition of E. H. Weber's schema of the circulation, a See also:scheme which presents a true and consistent theory. In 1826 See also:Jean See also: G. M.) ' See See also:Miscellaneous Works, ed. See also:Peacock (2 vols., London, 1855)- 2 See Marev, La Methode graph. dans See also:les sc. exper. (Paris, 1878). Magendie's See also:Journal, vol. viii. p. 272. Additional information and CommentsThere are no comments yet for this article.
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