Effects of changes in electrical potential difference on tubular potassium transport

To assess directly the role of the transepithelial potential difference (PD) on potassium concentration differences across distal tubular epithelium, continuous and stationary microperfusion experiments were done in tubules voltage-clamped over a wide range of lumen-negative potentials. Potassium was measured either chemically or in situ by potassium-sensitive microelectrodes. Distal cell PD measurements show that most of the potential drop induced by luminal current injection occurred across the luminal cell membrane. Experiments were done in rats either on a control or on a high potassium diet and after amiloride administration. Luminal potassium was highly sensitive to imposed electrical potential changes, attainment of a new steady-state intraluminal potassium concentration was rapid (less than 1 s), and higher luminal potassium concentrations were observed in animals in which potassium secretion had been stimulated. Similar slopes of tubular fluid-to-plasma potassium ratios versus transepithelial potential differences were observed in all experiments. All slopes intersected, at zero PD, at a luminal tubular fluid-to-plasma concentration ratio in excess of unity, indicating the presence of an active component of potassium secretion.

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Effects of flow rate and potassium intake on distal tubular potassium transfer

American Journal of Physiology-Legacy Content ◽

10.1152/ajplegacy.1975.228.4.1249 ◽

1975 ◽

Vol 228 (4) ◽

pp. 1249-1261 ◽

Cited By ~ 124

Author(s):

RN Khuri ◽

WN Strieder ◽

G Giebisch

Keyword(s):

Flow Rate ◽

Electrical Potential ◽

Isotonic Saline ◽

Distal Tubule ◽

Sodium Reabsorption ◽

Electrical Potential Difference ◽

High Potassium ◽

Flow Rates ◽

Potassium Intake ◽

Potassium Secretion

Potassium transport was studied across proximal and distal tubular epithelium in rats on a normal, low- and high-potassium intake during progressive loading with isotonic saline (150 mM) or a moderately hypersomotic urea (200 mM) sodium chloride (100 mM) solution. Free-flow micropuncture and recollection techniques were used during the development of diruesis and tubular fluid (TF) analyzed for inulin-14C, potassium (K) and sodium (Na). Tubular puncture sites were localized by neoprene filling and microdissection. During the large increase in tubular flow rates (10 times): 1) fractional potassium reabsorption fell along the proximal tubule, 2) TFk along the distal tubule remained constant and independent of flow rate in control and high-k rats; thus, net potassium secretion increased in proportion to and was limited by flow rate. 3) In low-K rats TF k fell; with increasing flow rates distal K secretion was not effectively stimulated. 4) Distal tubular sodium reabsorption increased in all animals with flow rate, but tubular Na-K exchange ratios varied greatly. It is suggested that whenever sodium delivery stimulates distal tubular potassium secretion it does so by 1) increasing volume distal tubular potasssium secretion and by 2) augmenting the transepithelial electrical potential difference (lumen negative).

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Electrical potential difference during laser welding

Journal of Plasma Physics ◽

10.1017/s002237781400049x ◽

2014 ◽

Vol 81 (1) ◽

Cited By ~ 4

Author(s):

H. Zohm ◽

G. Ambrosy ◽

K. Lackner

Keyword(s):

Laser Welding ◽

Electron Flux ◽

Electrical Potential ◽

Potential Drop ◽

Potential Difference ◽

Electrical Potential Difference ◽

Workpiece Surface ◽

Voltage Difference ◽

Contact Points ◽

Good Agreement

We present a new model for the generation of thermoelectric currents during laser welding, taking into account sheath effects at both contact points as well as the potential drop within the quasi-neutral plasma generated by the laser. We show that the model is in good agreement with experimentally measured electric potential difference between the hot and the cold parts of the welded workpiece. In particular, all three elements of the model are needed to correctly reproduce the sign of the measured voltage difference. The mechanism proposed relies on the temperature dependence of the electron flux from the plasma to the workpiece and hence does not need thermoemission from the workpiece surface to explain the experimentally observed sign and magnitude of the potential drop.

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Electrical potential difference, sodium absorption and potassium secretion by the human rectum during carbenoxolone therapy.

Gut ◽

10.1136/gut.16.4.277 ◽

1975 ◽

Vol 16 (4) ◽

pp. 277-284 ◽

Cited By ~ 14

Author(s):

A M Tomkins ◽

C J Edmonds

Keyword(s):

Electrical Potential ◽

Potential Difference ◽

Sodium Absorption ◽

Electrical Potential Difference ◽

Human Rectum ◽

Potassium Secretion

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Insulin action on membrane potential and glucose uptake: effects of high potassium

AJP Endocrinology and Metabolism ◽

10.1152/ajpendo.1985.249.1.e17 ◽

1985 ◽

Vol 249 (1) ◽

pp. E17-E25

Author(s):

K. Zierler ◽

E. M. Rogus ◽

R. W. Scherer ◽

F. S. Wu

Keyword(s):

Membrane Potential ◽

Insulin Action ◽

Potassium Concentration ◽

Electrical Potential ◽

Cell Swelling ◽

Electrical Potential Difference ◽

High Potassium ◽

High K ◽

External Potassium ◽

Stimulation Of

These experiments were designed to test the hypothesis that insulin-induced hyperpolarization is a link in the chain of events leading to stimulation of glucose transport. External potassium concentration, [K+]o, was increased by equimolar substitution of KCl for NaCl, a method known to cause cell swelling, and by substitution of [K+]o for [Na+]o with maintenance of constant [K+]o X [Cl-]o product, a method that does not cause cell swelling. When there was constant KCl product, even at 76.8 meq [K+]o insulin continued to hyperpolarize, although by only approximately 44% as much as in normal [K+]o, and insulin-stimulated 2-deoxyglucose uptake was only approximately 60% of that at normal [K+]o. With equimolar substitution of KCl for NaCl: electrical potential difference across cell membranes of surface fibers of rat caudofemoralis muscle decreased with logarithm [K+]o, in the presence or absence of insulin. Insulin-induced hyperpolarization decreased as [K+]o increased and disappeared at 36 mM [K+]o. The amount of insulin bound to its receptors in 1 h was not affected by [K+]o over the range studied. Insulin effects on membrane potential and on 2-deoxyglucose uptake, as both were altered by [K+]o, correlated well. As the probe moved in depth through the first six fibers there was stepwise decrease in depolarization in high [K+]o in the absence of insulin. Insulin hyperpolarized the deepest of these fibers, even when it did not hyperpolarize the outermost. The decrease in insulin-induced hyperpolarization as [K+]o increases is consistent with the hypothesis that insulin hyperpolarizes by decreasing the ratio PNa/PK.

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Effect of plasma [K+] on the DC potential and on ion distributions between CSF and blood

Journal of Applied Physiology ◽

10.1152/jappl.1975.39.6.1012 ◽

1975 ◽

Vol 39 (6) ◽

pp. 1012-1016 ◽

Cited By ~ 12

Author(s):

S. W. Bledsoe ◽

A. H. Mines

Keyword(s):

Potassium Concentration ◽

Electrical Potential ◽

Fold Increase ◽

Plasma Potassium ◽

Electrical Potential Difference ◽

Control Value ◽

Ion Distributions ◽

Arterial Ph ◽

Anesthetized Dogs ◽

Effective Role

Keeping the arterial pH at 7.4 and PaCO2 at 40 mmHg in eight anesthetized dogs, we acutely raised plasma potassium concentration from 3.4 to 8.2 meq/1, then allowed it to decay back to control levels. The cerebrospinal fluid (CSF)-blood electrical potential difference (pd) increased 13.2 mV per 10-fold increase in plasma [K+]. Again keeping arterial pH at 7.4 and PaCO2 at 40 mmHg, we elevated plasma [K+] in four dogs from 3.3 to 8.0 meq/1 and maintained this level for 6 h. We found 1) that the PD increased from a control value of +1.3 to +8.9mV, showing no tendency to decay over the 6 h; and 2) that the change in PD did not affect the distribution of Na+, K+, H+, Cl-, or HCO3- between blood and CSF over the 6 h. These results suggest that under these conditions the PD between CSF and blood may play no effective role in determining the distributions of these charged species by 6 h. These results are contrasted with recent findings which suggest that H+ and HCO3- are distributed according to passive forces between CSF and blood.

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