The Blood Vascular System of Nephtys (Annelida, Polychaeta)

1956 ◽  
Vol s3-97 (38) ◽  
pp. 235-249
Author(s):  
R. B. CLARK
Keyword(s):  
Body Wall ◽  
Vascular System ◽  
Close Association ◽  
Circulatory System ◽  
Ventral Surface ◽  
Blood Stream ◽  
Neurosecretory Cells ◽  
The Body ◽  
Dorsal Vessel ◽  
The Brain

The four longitudinal vessels of the circulatory system of Nephtys californiensis are dorsal, sub-intestinal, and neural, the latter being paired. There is a complete longitudinal circulation; the dorsal vessel communicates with the sub-intestinal by way of the proboscidial circulation and with the neural by way of the circum-oral vessels. In each middle and posterior segment segmental vessels from each of the longitudinal trunks carry blood to and from the parapodia and body-wall. The segmental circulation is completed by a circum-intestinal vessel connecting the dorsal and subintestinal vessels in each segment and an intersegmental branch connecting the dorsal and sub-intestinal segmental vessels. A trans-septal branch of the neural segmental vessel communicates with the sub-intestinal segmental vessel. This arrangement is modified in anterior segments which house the muscular, eversible pharynx, and no blood-vessels cross the coelom except by running through the body-wall. On anatomical grounds and by comparison with other polychaetes it seems likely that segmental is subordinate to longitudinal circulation. There are no endothelial capillaries such as have been described in some other polychaetes; instead there are numerous blindending vessels the walls of which are composed of the same three layers as other vessels and which are probably contractile. The dorsal vessel, where it is in contact with the ventral surface of the supra-oesophageal ganglion, forms a plexus in close association with a modified part of the brain capsule and a special axonal tract within the ganglion. It is thought that by way of this ‘cerebro-vascular complex’, hormones produced in the neurosecretory cells of the brain pass into the blood-stream.

scholarly journals Memoirs: On the Blood-Vascular System of the Earthworm Pheretima, and the Course of the Circulation in Earthworms

1921 ◽  
Vol s2-65 (259) ◽  
pp. 349-393
Author(s):  
KARM NARAYAN BAHL
Keyword(s):  
Body Wall ◽  
Vascular System ◽  
Blood System ◽  
The Body ◽  
Dorsal Vessel ◽  
The Third ◽  
Arterial Trunk ◽  
Venous Function ◽  
Circulation Of The Blood ◽  
Close Parallelism

1. The typical arrangement of the blood-system in Pheretima occurs in the region of the body behind the fourteenth segment, the first fourteen segments forming the cephalized region. The main longitudinal trunks are the same as in Lumbricus, except that the lateral neurals are absent as in Allolobophora. The dorsal vessel receives two pairs of dorso-intestinals and one pair of commissurals in each segment behind the cephalized region. 2. The intestinal blood-plexus is both an external and an internal one, and three regions can easily be distinguished. The first is internal, and extends from the fourteenth to the twenty-sixth segment; the second is both external and internal, is co existent with the typhlosole, and extends over the larger part of the gut; and the third is only external, and is confined to the rectal or post-typhlosolar part of the gut (last twenty-three to twenty-six segments) 3. The commissural vessel of Pheretima is a compound vessel, and represents both the ‘dorso-sous-nervien’ of Lumbricus and the intestino-tegumentary of Megascolex. The capillaries of the integument are not like those of Lumbricus but like those of Moniligaster, and there is a close ‘parallelism’ between an ‘artery’ and a ‘vein’ in the body-wall, in which the two pass into each other through a number of capillary loops. 4. There are four pairs of ‘hearts’ which connect the dorsal with the ventral vessel, and five pairs which supply blood directly to the various organs in the cephalized region. There are two pairs of non-contractile ‘anterior loops’ connecting the lateral oesophageals with the supra-intestinals, these loops being the counterpart of the connexions of the lateral oesophageals with the dorsal and the parietal in the tenth and twelfth segments respectively of Lumbricus. The subneural Tessel is absent in the first fourteen segments, and is continuous with the lateral oesophageals of the anterior region. 5. As regards the course of circulation of the blood, the chief fact is that the dorsal vessel is wholly ‘venous’ behind the ‘hearts’ and wholly ‘arterial’ in the region of the ‘hearts’ and in front (the whole of the cephalized region). The examination of valves and experiments by cutting and pinching the blood-vessels in Pheretima confirm the results of Johnstone for Lumbricus as regards the course of blood in dorsointestinals and commissurals and make Bourne's theory untenable. The ventral vessel is the arterial trunk throughout, while the venous function of the dorsal and subneural behind is taken up by the lateral oesophageals in the cephalized region. The thin-walled and non-contractile ‘loops’ of the tenth and eleventh segments must be distinguished from the thick walled and contractile ‘hearts’ of the other cephalized segments, the ‘loops’ being the channels for conveying blood from the lateral oesophageals to the supra-intestinals.

Morphology of Anomalocaris canadensis from the Burgess Shale

2014 ◽  
Vol 88 (1) ◽  
pp. 68-91 ◽  
Author(s):  
Allison C. Daley ◽  
Gregory D. Edgecombe
Keyword(s):  
Close Association ◽  
Dorsal Surface ◽  
Ventral Surface ◽  
The Body ◽  
Body Region ◽  
Morphological Description ◽  
Burgess Shale ◽  
Oral Cone ◽  
Stem Lineage ◽  
Posterior Body Region

Recent description of the oral cone of Anomalocaris canadensis from the Burgess Shale (Cambrian Series 3, Stage 5) highlighted significant differences from published accounts of this iconic species, and prompts a new evaluation of its morphology as a whole. All known specimens of A. canadensis, including previously unpublished material, were examined with the aim of providing a cohesive morphological description of this stem lineage arthropod. In contrast to previous descriptions, the dorsal surface of the head is shown to be covered by a small, oval carapace in close association with paired stalked eyes, and the ventral surface bears only the triradial oral cone, with no evidence of a hypostome or an anterior sclerite. The frontal appendages reveal new details of the arthrodial membranes and a narrower cross-section in dorsal view than previously reconstructed. The posterior body region reveals a complex suite of digestive, respiratory, and locomotory characters that include a differentiated foregut and hindgut, a midgut with paired glands, gill-like setal blades, and evidence of muscle bundles and struts that presumably supported the swimming movement of the body flaps. The tail fan includes a central blade in addition to the previously described three pairs of lateral blades. Some of these structures have not been identified in other anomalocaridids, making Anomalocaris critical for understanding the functional morphology of the group as a whole and corroborating its arthropod affinities.

*Grown MD CBD gummies Where To buy? Scam Pills | Alert* v1

2022 ◽  
Author(s):  
health not provided
Keyword(s):  
Circulatory System ◽  
Grape Seed ◽  
The Body ◽  
Secondary Effects ◽  
Psychological Issues ◽  
Primary Element ◽  
Grape Seed Oil ◽  
The Right ◽  
Sleeping Disorder ◽  
The Brain

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The Croonian Lecture, 1964 The release and fate of the transmitter liberated by adrenergic nerves

1965 ◽  
Vol 162 (986) ◽  
pp. 1-19 ◽  
Keyword(s):  
Skeletal Muscle ◽  
Blood Vessels ◽  
Vascular System ◽  
Sympathetic Innervation ◽  
Muscle Cells ◽  
Blood Stream ◽  
The Body ◽  
Adrenergic Nerves ◽  
Local Motion ◽  
Specific Enzyme

It is customary for Croonian lecturers, after expressing their thanks to the President and Council for the honour that they have received in being asked to give this lecture, to devote some time to a justification of their subject in terms of Mrs Croone’s suggestion that the lecture should deal with the advancement of natural knowledge on local motion. The first of these tasks, Mr President, I perform humbly and with deep gratitude, but at the same time with some surprise that Council in its wisdom should have chosen one so ill-fitted for the honour you have laid upon him. The second task is easier since my lecture will deal with the nerves which control the muscles surrounding the hollow organs of the body, blood vessels and bowels, and further justification as a theme dealing with local motion the most captious critic could not desire. Three years ago my former colleague Bernard Katz gave the Croonian Lecture on ‘ Transmission of impulses from nerve to muscle’ in which he described our present knowledge of the mechanism of the chemical mediation interposed between nerve and skeletal muscle and summarized his own brilliant contributions to this, to me, fascinating subject. Today I am dealing again with transmission from nerve to muscle, but in a different system and, I am afraid, at a quite different and lower intellectual level than that of Katz. The idea of chemical transmission from nerve to effector cell came first to T. R. Elliott in 1904 as a result of his observation, in an extensive comparative study, of the close similarities between the actions of adrenaline injected intravenously and the effects of stimulating nerves belonging to the sympathetic system. These nerves we should now call in Dale’s (1933) terminology the adrenergic nerves, those transmitting their effects whether excitatory or inhibitory by the liberation at their endings of a ‘minute charge’ of the catecholamine adrenaline or one of its analogues. The cells upon which these nerves exert their action are the smooth muscle cells controlling the movements of the hollow viscera, intestines, reproductive tract and so on, and of the muscle cells of the vascular system that regulate the diameter of the blood vessels. These are processes that do not demand high precision of timing nor do they apparently require the instant turning on and off of transmitter action with which we have grown familiar in the junction between nerve and skeletal muscle. At this junction, as Katz showed, liberation and action of acetylcholine and its inactivation by the specific enzyme cholinesterase are over in a few milliseconds, and there is no reason to believe that the liberated transmitter in the untreated junction can ever diffuse more than a few microus from its site of action. It is hemmed in by barriers of specific cholinesterase, and these are reinforced by barriers of the non-specific enzyme in blood and tissue fluids. This narrow coarctation of the transmitter acetylcholine in space and time seems, however, to be confined to places where precise timing is required, such as at the neuromuscular junction and in the ganglionic and central nervous synapse. When it is liberated as the transmitter from nerves to blood vessels, or to secretory glands, it can escape some way from its site of liberation and persist long enough to be detected by skeletal muscles sensitized by denervation, as is seen in the Sherrington, Rogowitz and Vulpian-Heidenhain phenomena. I have laboured a little this question of diffusion and action at a distance of transmitter because it constitutes prima facie one of the most striking differences between the adrenergic and the cholinergic transmitters in at least the mammalian body. It was indeed because the liberated adrenergic transmitter escaped into the blood stream and could be detected by another tissue or organ, sometimes, but not necessarily, specially sensitized, that W. B. Cannon and his colleagues in the 30’s were able to add so much to our knowledge of sympathetic innervation. Nevertheless, in spite of the relative stability of the adrenergic transmitter and its ready detection in the blood stream, little had been discovered about the quantitative aspects of its liberation and metabolism some 50 years after its existence had been postulated, whereas we now have, and have had for 30 years, quite reasonably complete information about the liberation, storage and metabolism of the unstable and ephemeral acetylcholine.

scholarly journals STROKE

2006 ◽  
Vol 12 (02) ◽  
pp. 114-117
Author(s):  
ASAD ALI ◽  
AHMAD DANYAL ◽  
AFTAB TURABI
Keyword(s):  
Subarachnoid Hemorrhage ◽  
Vascular System ◽  
Medical Problem ◽  
The Body ◽  
Cerebral Lesion ◽  
Cerebral Function ◽  
Careful Monitoring ◽  
Who Criteria ◽  
The Brain

Stroke was defined according to WHO criteria as rapidly developingsymptoms and / or signs of focal and at times global loss of cerebral function with no apparent cause other than thatof vascular disease1. Stroke is grossly divided into either2 1). Thrombotic. 2). Embolic. 3).Hemorrhagic type (Whichmay be either intra cerebral bleed or subarachnoid hemorrhage). The brain, like other organs of the body, requires anadequate vascular system in order to supply it with nutrients and oxygen and to remove metabolic wastes and carbondioxide. Stabilization of medical problem with careful monitoring, and active prevention and timely management ofsecondary complications are of the utmost important for reducing stroke morality rates and avoiding further ischemicbrain injury. For the ischemic cerebral lesion itself, as yet no treatment or combination of treatment has beenestablished to be universally effective3. However, current studies allow for the following 5 potential therapeutic areasto be identified.

scholarly journals The Blood-system in the Serpulimorpha (Annelida, Polychaeta)

1950 ◽  
Vol s3-91 (16) ◽  
pp. 369-378
Author(s):  
JEAN HANSON
Keyword(s):  
Blood Supply ◽  
Peripheral Blood ◽  
Body Wall ◽  
Blood System ◽  
The Body ◽  
Dorsal Vessel ◽  
The Family ◽  
Body Wall Musculature

1. The blood-system in sabellids of the following genera is described: Sabella, Potamilla, Branchiomma, Dasychone, Amphiglena, Fabricia, Jasmineira, Dialychone, and Myxicola. 2. The central blood-system of Sabella is typical of the family, but the peripheral blood-system is variable. 3. The dorsal vessel lacks the valve and muscular sphincter found in some serpulids. 4. Lateral vessels are present only in Sabella and Dasychone. 5. The differences and similarities between sabellid and serpulid blood-systems are discussed. Special attention is given to the functions of sub-epidermal and coelomic capillaries and the blood-supply of the body-wall musculature.

Diatoms and Forensic Science

2007 ◽  
Vol 13 ◽  
pp. 181-190
Author(s):  
Benjamin P. Horton
Keyword(s):  
Forensic Science ◽  
Cause Of Death ◽  
Blood Stream ◽  
The Body ◽  
Naturally Occurring ◽  
Analogue Matching ◽  
Informal Assessment ◽  
Diatom Test ◽  
The Brain ◽  
Site Of Drowning

The application of diatom analysis in determining whether drowning was the cause of death has proved to be a valuable tool in forensic science. The basic principal of the “diatom test” in drowning is based on inference that diatoms are present in the medium where the possible drowning took place and that the inhalation of water causes penetration of diatoms into the alveolar system and blood stream, and thus, their deposition into the brain, kidneys, and other organs.I provide an informal assessment of “reliability” of the “diatom test” through correlations between control samples and samples from organs and clothing in two case studies. In studies, all organ and clothing samples except one had matching analogues in the modern diatom dataset from the body recovery sites, reinforcing drowning as the cause of death. The analogue matching provides further information on the precise site of drowning, in particular differentiating between drowning in a bathtub versus a naturally occurring body of water.

1. On the Structure of the Body-wall in the Spionidæ

1878 ◽  
Vol 9 ◽  
pp. 123-129
Author(s):  
W. C. M'Intosh
Keyword(s):  
Body Wall ◽  
Ventral Surface ◽  
The Body ◽  
Middle Line ◽  
Structural Examination ◽  
The Family ◽  
Rounded Form ◽  
Basement Layer ◽  
External Form ◽  
Complex Manner

In regard to external form, Nerine foliosa, Sars, is generally taken as the type of the family, and therefore it may be selected for structural examination in the first instance. Anteriorly the pointed snout is completed by the intricate interlacing of the muscular fibres beneath specially thickened cuticular and hypodermic layers. As soon as the body-wall assumes a rounded form, a layer of circular and oblique muscular fibres occurs beneath the hypoderm, the majority having the latter (i.e., the oblique) direction. In the centre of the area the oesophagus is suspended by strong muscular bundles (the most conspicuous of which are vertical) passing from the hypodermic basement-layer in the middle line superiorly to be attached to the œsophagal wall. A second series, as they descend to their insertion at the ventral surface, give lateral support to the tube; while a third group interlace in a complex manner, and, with the blood-vessels, fill up the space between the œsophagus and the wall of the body.

scholarly journals Contractile pericytes determine the direction of blood flow at capillary junctions

2020 ◽  
Vol 117 (43) ◽  
pp. 27022-27033
Author(s):  
Albert L. Gonzales ◽  
Nicholas R. Klug ◽  
Arash Moshkforoush ◽  
Jane C. Lee ◽  
Frank K. Lee ◽  
...  
Keyword(s):  
Blood Flow ◽  
Circulatory System ◽  
The Body ◽  
Capillary Network ◽  
Transitional Region ◽  
Capillary Networks ◽  
Efficiency And Effectiveness ◽  
The Central Nervous System ◽  
Essential Function ◽  
The Brain

The essential function of the circulatory system is to continuously and efficiently supply the O2 and nutrients necessary to meet the metabolic demands of every cell in the body, a function in which vast capillary networks play a key role. Capillary networks serve an additional important function in the central nervous system: acting as a sensory network, they detect neuronal activity in the form of elevated extracellular K+ and initiate a retrograde, propagating, hyperpolarizing signal that dilates upstream arterioles to rapidly increase local blood flow. Yet, little is known about how blood entering this network is distributed on a branch-to-branch basis to reach specific neurons in need. Here, we demonstrate that capillary-enwrapping projections of junctional, contractile pericytes within a postarteriole transitional region differentially constrict to structurally and dynamically determine the morphology of capillary junctions and thereby regulate branch-specific blood flow. We further found that these contractile pericytes are capable of receiving propagating K+-induced hyperpolarizing signals propagating through the capillary network and dynamically channeling red blood cells toward the initiating signal. By controlling blood flow at junctions, contractile pericytes within a functionally distinct postarteriole transitional region maintain the efficiency and effectiveness of the capillary network, enabling optimal perfusion of the brain.

Memoirs: On the Communication between the Cœlom and the Vascular System in the Leech, Hirudo medicinalis

1899 ◽  
Vol s2-42 (168) ◽  
pp. 477-495
Author(s):  
EDWIN S. GOODRICH
Keyword(s):  
Body Wall ◽  
Vascular System ◽  
The Body ◽  
The Other ◽  
True Nature ◽  
Annular Channels ◽  
Abdominal Vessels ◽  
Two Systems ◽  
Imperfect Knowledge ◽  
The One

According to the foregoing account, the evidence of carefully executed injections strongly favours the view that a continuity exists between the contractile vascular system and the noncontractile sinus system in Hirudo. This continuity is proved to exist in various regions of the body by means of serial sections. The communication takes place through the capillary systems. The hæmolymph system of Hirudo consists of four main longitudinal trunks, sending out transverse branches to the body-wall. The dorsal branches of the lateral vessels pass into small annular vessels communicating with the plexus of minute capillaries in the epidermis. From these, again, arise capillaries going to small sinuses which run into the lateral transverse sinuses, and so into the dorsal sinus. Similarly (he ventral sinus sends annular sinuses along the ventral region of the body-wall opening into the epidermal plexus, whence arise capillaries joining the latero-abdominal vessels. Continuity between the two systems has also been shown to take place by means of capillaries on the wall of the alimentary canal, and probably exists on the other internal organs of the body. Two questions still remain to be solved: firstly, as to the circulation of the hæmolymph; secondly, as to the exact homology of the channels in which it flows. With respect to the first of these problems, I have no direct observations to record; but it may be pointed out that the presence of the valves described above show, at least, that the hæmolymph must flow in a constant direction--that there is a real circulation, not a mere motion backwards and forwards. It seems to me extremely probable that the annular vessels collect the oxygenated blood from the epidermal plexus, and carry it into the latero-dorsal and latero-lateral vessels, whence it would be pumped into the lateral vessels. From these some of the hæmolymph must be carried by the latero-abdominal vessels to the various organs of the body, and to the ventral cutaneous plexus. The annular sinuses would collect it from this plexus and carry it into the ventral sinus. The abdominodorsals and the dorsal sinus would appear to supply the dorsal and lateral cutaneous plexus. We are left in considerable uncertainty as to the true nature of some of the spaces. That the lateral vessels belong to the real vascular system, and that the ventral sinus and perinephrostomial sinuses belong to the true cœlomic system, seems to be clearly established both by comparative anatomy and by the embryological researches of Bürger (2). This observer, however, could not trace the dorsal sinus to a cœlomic origin, and since its branches bear the same relation to the cutaneous plexus as those of the latero-abdominal vessels, I am inclined to think that the dorsal sinus may represent the dorsal vessel of other annelids. In that case the cœlomic cavities do not persist dorsally, or have never reached the median dorsal region in the Gnathobdellidæ. The annular channels may possibly represent the annular cœlomic lacunæ so well described and figured by Oka in Clepsine (10), and it may perhaps be through them that the chief communication between the cœlom and the vascular system has been established. The observation of the some-what variable relations of these annular channels tends to support this view. With the very imperfect knowledge of the development of the cœlom and blood-vessels in Hirudo at our disposal, we cannot say for certain at present where the one ends and the other begins, nor whether a given capillary really belongs to the one or the other. Nor can we safely conjecture how the continuity has actually taken place. But one thing seems fairly certain, namely, that it is not only by means of the botryoidal channels that the communication has been brought about. It is very tempting to compare the leech with the Vertebrate, in which a third system of spaces--the lymphatic system--has been interpolated, allowing a communication to take place between the originally distinct cœlom and blood-vascular system.1 But the botryoidal tissue is not so inter-polated in the case of Hirudo; if it were obliterated, the two systems would still be in free continuity by means of capillaries. The botryoidal channels would seem to be rather of the nature of a by-path, through which the hæmolymph does not necessarily circulate. In this connection it should be mentioned that in sections they are rarely seen to be as much distended with the fluid as the neighbouring capillaries of similar size. Whatever may be the process whereby the continuity between the cœlom and vascular system has been established in the Gnathobdellidæ, there can be little doubt that it is a secondary condition, and that the structure of such a form as Acanthobdella, in which a closed blood-system lies in a normally developed cœlom, is really the more primitive.

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