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Conduction pathway

The carbon blacks used in plastics are usually different from the carbon blacks used in mbber. The effect of carbon black is detrimental to the physical properties of plastics such as impact strength and melt flow. Electroconductive grades of carbon black have much higher surface areas than conventional carbon blacks. The higher surface areas result in a three-dimensional conductive pathway through the polymer at much lower additive levels of the carbon black. The additive concentrations of electroconductive carbon blacks is usually j to that of a regular carbon black (132). [Pg.296]

Enhanced automaticity occurs in hypoxia, hypokalemia, hypercarbia, excessive sympathetic nervous system stimulation, or high concentrations of catecholamines. These conditions may lead to arrhythmias. Decreased automaticity may also lead to production of arrhythmias by enhancing ectopic activity in latent pacemakers (ectopic foci) or by altering conductivity and refractoriness in conduction pathways of myocardium. [Pg.111]

An electrically conductive pathway (4) physically linking the two materials... [Pg.356]

For all other members of the TRP family it still has to be shown whether the presumptive pore loop or other protein domains actually line the ion conducting pathway of the channel. Based on the results showing that expression of most TRPC channels yields currents carried by Na+and Ca2+, and that expression of TRPM4 and TRPM7 channels yields currents carried by Na+ but not by Ca2+(TRPM4) or even currents carried by Mg2+or Ca2+(TRPM7), it seems likely that the pore structures of these channel proteins vary considerably. [Pg.1244]

Clearly, cardiac function may not be addressed exclusively on the basis of describing the working mechanisms of single cells. Both normal and disturbed heart rhythms are based on a spreading wave of electrical excitation, the meaningful investigation of which requires conduction pathways of at least hundreds if not thousands of cells in length. [Pg.137]

O Paroxysmal supraventricular tachycardia is caused by reentry that includes the AV node as a part of the reentrant circuit. Typically, electrical impulses travel forward (antegrade) down the AV node and then travel back up the AV node (retrograde) in a repetitive circuit. In some patients, the retrograde conduction pathway of the reentrant circuit may exist in extra-AV nodal tissue adjacent to the AV node. One of these pathways usually conducts impulses rapidly, while the other usually conducts impulses slowly. Most commonly, during PSVT the impulse conducts antegrade through the slow... [Pg.123]

From the SA node, the heart beat spreads rapidly throughout both atria by way of the gap junctions. As mentioned previously, the atria are stimulated to contract simultaneously. An interatrial conduction pathway extends from the SA node to the left atrium. Its function is to facilitate conduction of the impulse through the left atrium, creating the atrial syncytium (see Figure 13.3). [Pg.171]

An internodal conduction pathway also extends from the SA node and transmits the impulse directly to the atrioventricular (AV) node. This node is located at the base of the right atrium near the interventricular septum, which is the wall of myocardium separating the two ventricles. Because the atria and ventricles are separated from each other by fibrous connective tissue, the electrical impulse cannot spread directly to the ventricles. Instead, the AV node serves as the only pathway through which the impulse can be transmitted to the ventricles. The speed of conduction through the AV node is slowed, resulting in a slight delay (0.1 sec). The cause of this AV nodal delay is partly due to the smaller fibers of the AV node. More importantly, however, fewer gap junctions exist between the cells of the node, which... [Pg.171]

Figure 13.3 Route of excitation and conduction in the heart. The heart beat is initiated in the sinoatrial (SA) node, or the pacemaker, in the right atrium of the heart. The electrical impulse is transmitted to the left atrium through the interatrial conduction pathway and to the atrioventricular (AV) node through the intemodal pathway. From the AV node, the electrical impulse enters the ventricles and is conducted through the AV bundle, the left and right bundle branches, and, finally, the Purkinje fibers, which terminate on the true cardiac muscle cells of the ventricles. Figure 13.3 Route of excitation and conduction in the heart. The heart beat is initiated in the sinoatrial (SA) node, or the pacemaker, in the right atrium of the heart. The electrical impulse is transmitted to the left atrium through the interatrial conduction pathway and to the atrioventricular (AV) node through the intemodal pathway. From the AV node, the electrical impulse enters the ventricles and is conducted through the AV bundle, the left and right bundle branches, and, finally, the Purkinje fibers, which terminate on the true cardiac muscle cells of the ventricles.
The autonomic nervous system exerts the primary control on heart rate. Because the sympathetic and parasympathetic systems have antagonistic effects on the heart, heart rate at any given moment results from the balance or sum of their inputs. The SA node, which is the pacemaker of the heart that determines the rate of spontaneous depolarization, and the AV node are innervated by the sympathetic and parasympathetic systems. The specialized ventricular conduction pathway and ventricular muscle are innervated by the sympathetic system only. [Pg.183]

The mechanism of these effects involves enhanced depolarization of these cells due to decreased potassium permeability and increased sodium and calcium permeability. With fewer K+ ions leaving the cell and with more Na+ and Ca++ ions entering the cell, the inside of the cell becomes less negative and approaches threshold more rapidly. In this way, action potentials are generated faster and travel through the conduction pathway more quickly so that the heart can generate more heartbeats per minute (see Figure 14.1). [Pg.184]

Ionic-conduction Pathways in Hybrid Membrane Materials... [Pg.318]

Fig. 10.6 (A) Stick representation of the packing of 3 in the crystal, showing the formation of directional tubular conduction pathways (B) schematic representation ofthe hierarchically organized system 3 (top) self-organization in solution and (bottom) sol-gel transcription of encoded molecular features into a hybrid heteropolysiloxane matrix [18]. Fig. 10.6 (A) Stick representation of the packing of 3 in the crystal, showing the formation of directional tubular conduction pathways (B) schematic representation ofthe hierarchically organized system 3 (top) self-organization in solution and (bottom) sol-gel transcription of encoded molecular features into a hybrid heteropolysiloxane matrix [18].
Successive H-bond urea self-assembly of 4 and sol-gel transcription steps yield preferential conduction pathways within the hybrid membrane materials. Crystallographic, microscopic and transport data confirm the formation of self-organized molecular channels transcribed in solid dense thin-layer membranes. The ionic transport across the organized domains illustrates the power of the supramolecular approach for the design of continual hydrophilic transport devices in hybrid membrane materials by self-organization (Figure 10.8) [42-44]. [Pg.321]

S-S contacts. However, conducting pathways are not formed effectively by the stacking of the cation radicals [26]. [Pg.46]

You will be expected to have an understanding of action potentials in nerves, cardiac pacemaker cells and cardiac conduction pathways. [Pg.185]

See other pages where Conduction pathway is mentioned: [Pg.296]    [Pg.296]    [Pg.108]    [Pg.73]    [Pg.305]    [Pg.514]    [Pg.515]    [Pg.516]    [Pg.1306]    [Pg.126]    [Pg.217]    [Pg.12]    [Pg.721]    [Pg.111]    [Pg.114]    [Pg.373]    [Pg.373]    [Pg.479]    [Pg.12]    [Pg.330]    [Pg.22]    [Pg.33]    [Pg.716]    [Pg.98]    [Pg.331]    [Pg.332]   
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See also in sourсe #XX -- [ Pg.4 , Pg.109 ]



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