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Tubular cells

Tubular Cells. Although the tubular nickel electrode invented by Edison is ahnost always combined with an iron negatwe electrode, a small quantity of cells is produced in wliich nickel in the tubular fomi is used with a pocket cadniium electrode. Tliis type of cell construction is used for low operating temperature environments, where iron electrodes do not perfomi well or where charging current must be limited. [Pg.547]

Cadmium is effectively accumulated in the kidneys. When the cadmium concentration exceeds 200 gg/g in the kidney cortex, tubular damage will occur in 10% of the population, and proteins begin to leak into urine (proteinuria). When the concentration of cadmium in the kidney cortex exceeds 300 pg/g, the effect is seen in 50% of the exposed population. Typically, excretion of low-molecular weight proteins, such as beta-microglobulin, is increased, due to dysfunction of proximal tubular cells of the kidney. The existence of albumin or other high-molecular weight proteins in the urine indicates that a glomerular injury has also taken place. The excretion of protein-bound cadmium will also be increased. [Pg.269]

Rohren-halter, m. tube (or pipe) holder, tube (or pipe) clamp, -kassie, /. pur ng cassia, -kleuune, /. tube clamp, -kiibler, m. tubular condenser, tube condenser tubular cooler, -libelle, /. spirit level, air level, -lot, n. pipe solder, -manna, /. flake manna, -nudeln, /.pi. macaroni, -ofen, m. tube furnace (for heating tubes liable to explosion) pipe still, -pulver, n. (Expl.) perforated powder, -struktur, /. tubular structure, -substanz, /. (Anat.) medullary substance, -trager, m. tube (or pipe) support, -wachs, n. petroleum ceresin. -werk, n. tubing piping tube mill, -wischer, m. tube brush, -wulst, n. tubular tore, doughnut , -zelle, /. tubular cell, specif. (Bot.) tracheid. [Pg.368]

In the periphery, dopamine receptor levels are generally lower than those observed in brain, particularly in comparison to striatal dopamine receptor levels. Due to these low levels, knowledge of receptor distribution in the periphery is not yet comprehensive. Nevertheless, Dl-like receptors have been reported in the parathyroid gland and in the tubular cells of the kidney. D2-like dopamine receptors have also been observed in the kidney. In addition, dopamine D2 and D4 receptors have been found in the adrenal cortex, where they modulate aldosterone secretion. The... [Pg.440]

The kidney contains the major site of renin synthesis, the juxtaglomerular cells in the wall of the afferent arteriole. From these cells, renin is secreted not only into the circulation but also into the renal interstitium. Moreover, the enzyme is produced albeit in low amounts by proximal tubular cells. These cells also synthesize angiotensinogen and ACE. The RAS proteins interact in the renal interstitium and in the proximal tubular lumen to synthesize angiotensin II. In the proximal tubule, angiotensin II activates the sodium/hydrogen exchanger (NHE) that increases sodium reabsorption. Aldosterone elicits the same effect in the distal tubule by activating epithelial sodium channels (ENaC) and the sodium-potassium-ATPase. Thereby, it also induces water reabsotption and potassium secretion. [Pg.1067]

Potassium balance is also primarily regulated by the kidney via the distal tubular cells. Reduction in nephron mass decreases tubular secretion of potassium, leading to hyperkalemia. Hyperkalemia is estimated to affect more than 50% of patients with stage 5 CKD.28... [Pg.381]

Apparatus. A Coleman Junior Model 6A spectrophotometer, with tubular cells 9 mm. in diameter, is used (Catalog No. 6-302). [Pg.192]

In some human studies where clinical chemistry measurements but no renal biopsies were performed, the only parameter of renal function shown to be affected was an increase in the levels of NAG in the urine. NAG is a lysosomal enzyme present in renal tubular cells that has been shown to be a sensitive indicator of early subclinical renal tubular disease. The mechanism by which lead affects the release of NAG from renal tubular cells is not known, but it is suggested that lead could attach to kidney cell membranes and alter membrane permeability (Chia et al. 1994). [Pg.267]

The lead-induced nephropathy observed in humans and rodents shows a comparable early pathology (Goyer 1993). However, in rodents, proximal tubular cell injury induced by lead can progress to adenocarcinomas of the kidney (see Section 2.2.3.8). The observation of lead-induced kidney tumors in rats may not be relevant to humans. Conclusive evidence for lead-induced renal cancers (or any other type of cancer) in humans is lacking, even in populations in which chronic lead nephropathy is evident. [Pg.273]

Aldosterone acts on the distal tubule of the nephron to increase sodium reabsorption. The mechanism of action involves an increase in the number of sodium-permeable channels on the luminal surface of the distal tubule and an increase in the activity of the Na+-K+ ATPase pump on the basilar surface of the tubule. Sodium diffuses down its concentration gradient out of the lumen and into the tubular cells. The pump then actively removes the sodium from cells of the distal tubule and into the extracellular fluid so that it may diffuse into the surrounding capillaries and return to the circulation. Due to its osmotic effects, the retention of sodium is accompanied by the retention of water. In other words, wherever sodium goes, water follows. As a result, aldosterone is very important in regulation of blood volume and blood pressure. The retention of sodium and water expands the blood volume and, consequently, increases mean arterial pressure. [Pg.133]

Fig. 9.1 Schematic diagram depicting drug transporters and their subcellular localization in the human small intestinal enterocyte (A), hepatocyte (B), and renal tubular cell (C). Fig. 9.1 Schematic diagram depicting drug transporters and their subcellular localization in the human small intestinal enterocyte (A), hepatocyte (B), and renal tubular cell (C).
Ishido, M.S. Homma-Takeda, C. Tohyama, and T. Suzuki. 1998. Apoptosis in rat renal proximal tubular cells induced by cadmium. Jour. Toxicol. Environ. Health 55A 1-12. [Pg.73]

In an earlier study, there were renal tubular cell adenomas in 5/50 Osbome-Mendel rats receiving doses of 212 mg/kg/day but no tumors in 49 animals receiving 423 mg/kg/day or in 20 vehicle control rats (Weisburger 1977). Despite the lack of tumors, there was a high incidence of nephropathy (18-66%) in exposed male and female rats. [Pg.94]

FIGURE 6.6 High power density (HPD) SOFC, consisting of a flattened tube with two flat faces. The vertical struts between the two flat faces provide shorter paths for the electronic current collection, eliminating the need for all of the electronic current to travel around the circumference of the cathode, as in the standard tubular cell design shown in Figure 6.5 [48], Reprinted from [48] with permission from Elsevier. [Pg.253]

Although cathode-supported tubular SOFCs in large-scale stacks are the type of SOFC stack most widely commercialized, recent alternative tubular cell designs have been developed with anode-supported designs for smaller-power applications. Cells in these stacks have diameters on the order of several millimeters rather than centimeters,... [Pg.253]

Planar SOFCs have received increasing attention recently as an alternative to tubular cells due to their higher power densities, short current paths, and corresponding... [Pg.254]

Once the structural support layers have been fabricated by extrusion or EPD for tubular cells or by tape casting or powder pressing for planar cells, the subsequent cell layers must be deposited to complete the cell. A wide variety of fabrication methods have been utilized for this purpose, with the choice of method or methods depending on the cell geometry (tubular or planar, and overall size) materials to be deposited and support layer material, both in terms of compatibility of the process with the layer to be deposited and with the previously deposited layers, and desired microstructure of the layer being deposited. In general, the methods can be classified into two very broad categories wet-ceramic techniques and direct-deposition techniques. [Pg.256]


See other pages where Tubular cells is mentioned: [Pg.584]    [Pg.585]    [Pg.380]    [Pg.564]    [Pg.203]    [Pg.708]    [Pg.819]    [Pg.90]    [Pg.106]    [Pg.137]    [Pg.170]    [Pg.803]    [Pg.295]    [Pg.376]    [Pg.1191]    [Pg.66]    [Pg.286]    [Pg.138]    [Pg.393]    [Pg.173]    [Pg.317]    [Pg.127]    [Pg.132]    [Pg.135]    [Pg.17]    [Pg.112]    [Pg.112]    [Pg.112]    [Pg.239]    [Pg.252]    [Pg.252]    [Pg.255]    [Pg.259]    [Pg.264]   
See also in sourсe #XX -- [ Pg.451 , Pg.463 ]

See also in sourсe #XX -- [ Pg.274 , Pg.278 , Pg.281 ]




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Alternative Tubular Cell Designs

Cell culture models renal tubular epithelial cells

Electrochemical cell tubular

Human primary renal proximal tubular cells

Human proximal tubular cell line

Kidney tubular cells

Micro-tubular cell development

Mucinous tubular and spindle-cell

Proximal Tubular Cells and their Functions

Proximal tubular cells

Proximal tubular lining cells

Rapid and Efficient Methods for the Generation of Proximal Tubular-Like Cells

Renal proximal tubular cells

Renal tubular cells

Sealless tubular cell

Sodium, transport, tubular cells

Solid oxide fuel cells Westinghouse tubular cell

Solid oxide fuel cells tubular design

Solid oxide fuel cells tubular-type

Stacks with Tubular Cells

Targeting to the Proximal Tubular Cell

Tubular Cell Design (Seal-Less)

Tubular Cell Stack

Tubular cells and stacks

Tubular cells lead acid

Tubular cells mercury exposure

Tubular cells tubulitis

Tubular cells urinary biomarkers

Tubular detector cell

Tubular epithelial cell damage

Tubular epithelial cells

Tubular fuel cell design

Tubular solid oxide fuel cell

Tubular stacked fuel cells

Westinghouse tubular cell

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