Erythrocyte and Plasma Lipids in Terminal Renal Insufficiency

Bleiber, R; Eggert, W; Reichmann, G.; Kunze, D

doi:10.1159/000207381

Cited by 12 publications

(4 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In fact, cells from uremic patients show a decrease in the parameter which mea sures a transport of Na+ with the properties of a nonspe cific 'leak' across the lipid bilayer of the cell membrane [7]. Changes in the lipid composition and distribution of the red blood cell membrane, as those previously re ported in uremic patients [8,9], might be involved in the observed alteration in passive Na+ fluxes. In addition, this alteration may be partially responsible for the low Na+ concentration found in erythrocytes from hemodi alysis patients.…”

mentioning

confidence: 69%

Uremia and Red Blood Cell Sodium Transport

Díez¹,

Virto²,

Yap³

et al. 1986

Nephron

View full text Add to dashboard Cite

mentioning

confidence: 69%

Uremia and Red Blood Cell Sodium Transport

Díez¹,

Virto²,

Yap³

et al. 1986

Nephron

View full text Add to dashboard Cite

“…Patients with uremia have been found to have not only a decrease in LCAT activity, 40 but also an increased activity of phospholipase A 2 . 41 Conflicting results have been obtained from studies analysing the differences in phospholipid concentrations in blood plasma of patients with renal insufficiency, chronic renal failure and uremia (when compared with healthy volunteers): Bleiber et al 42 found an increase in all phospholipids except phosphatidylserine, Gillet et al 40 found a decrease of LPC, Vecino et al 41 found similar levels of LPC but an increase of PC, whereas Kalofoutis et al 43 found an increase for sphingomyelin, phosphatidylethanolamine and cardiolipin, but a decrease for phosphatidylinositol. In patients with nephrotic syndrome variations in plasma LCAT activity could also be found.…”

Section: -26mentioning

confidence: 99%

³¹P NMR spectroscopy of blood plasma: determination and quantification of phospholipid classes in patients with renal cell carcinoma

Süllentrop¹,

Moka²,

Neubauer³

et al. 2002

NMR in Biomedicine

View full text Add to dashboard Cite

Advanced renal cell carcinoma (RCC) has a poor prognosis and is characterized by an unpredictable clinical course. The aim of this study was to assess the systemic phospholipid distribution as a possible marker of tumor stage and tumor spread beyond the kidney. To this end, the effect of renal cell carcinoma (RCC) on phospholipid concentrations in blood plasma using 31P NMR spectroscopy was studied in: (a) 29 patients with RCC prior to nephrectomy; (b) 19 healthy volunteers; (c) three patients with other renal tumors (renal metastases of bronchial carcinoma and of renal pelvic carcinoma, and a benign renal tumor). Furthermore, the phospholipid concentrations of eight patients of group (a) were determined 6 months after nephrectomy, when they were in remission. We found considerable deviations in the concentrations of the lysophosphatidylcholines (LPC1, LPC2) in both male and female patients with RCC compared to healthy volunteers (male--LPC1 0.217+/-0.062 vs 0.297+/-0.049 mmol/l, LPC2 0.036+/-0.014 vs 0.068+/-0.024 mmol/l; female--LPC1 0.195+/-0.071 vs 0.296+/-0.044 mmol/l, LPC2 0.037+/-0.027 vs 0.044+/-0.014 mmol/l). In addition, female patients with RCC showed lower concentrations of phosphatidylcholines (PC; 1.409+/-0.268 vs 1.947+/-0.259 mmol/l). The low phospholipid concentrations normalized for patients in remission. Phospholipid concentrations were found to depend on tumor stage and metastatic spread. The deviations in phospholipid concentrations (LPC1, LPC2, PC) observed may be attributable to systemic effects caused by the tumor as well as changes in enzyme activities.

show abstract

“…In contrast to findings from Quarello et al 16 ) , the authors have found that the passive Na + permeability in the patients with pre-dialytic uremia was markedly decreased compared to that in normal subjects (p<10 −5 ), but its value in the post-dialytic group tended to recover to a normal level, which was consistent with a previous report by Diez et al 18 ) . Although the exact mechamism for inhibition of passive Na + permeability in chronic uremia is as yet uncertain, changes in the lipid composition and distribution of the RBC membranes, as Bleiber et al previously reported in uremic patients, might be involved in the observed alteration in passive Na + fluxes 34 ) .…”

Section: Discussionmentioning

confidence: 96%

Erythrocyte Sodium Transport in Dialyzed Uremic Patients

Yoon

Kim

Koo

et al. 1989

Korean J Intern Med

View full text Add to dashboard Cite

To investigate the status of the Na+ concentration and ionic fluxes in red cells of human subjects with dialyzed chronic uremia, the authors measured the Na+-K+ pump activity as well as Na+-K+ cotransport (CoT), Na+-Li+ countertransport (CTT) and Na+ passive permeability in erythrocytes from 37 normal subjects and 23 chronic uremic patiens receiving maintenance hemodialysis. The mean intracellular Na+ concentration [Na+]i value in the pre-dialytic group was significantly lower than that in control subjects (p<.0001), but tended to recover to the normal value of [Na+]i in the post-dialytic group. The mean intracellular K+ concentration value in the post-dialytic group was significantly higher than that of the control group (p<.001), but not significantly different from that of the pre-dialytic group. It was found that the Na+-K+ pump activity of erythrocytes in the pre- and post-dialytic groups markedly decreased over that of the normal control group with statistical significance (p<.0001, respectively). The Na+-K+ pump activity in the post-dialytic group, however, tended to recover, but not significantly. The rate constant for ouabain-sensitive Na+ efflux in the post-dialytic group was significantly decreased over that of the normal controls (p<.05). The authors observed a significant decrease of the Na+ CoT value (p<.001 respectively) and rate constant for Na+ CoT (p<.05, respectively) in the patients with pre- and post-dialytic uremia vs. that of normal subjects. Also, the authors observed a marked decrease of the Na+-Li+ CTT value in the patients in the pre- and post-dialytic groups than that of the control subjects (p<.05, respectively). Passive Na+ permeability in the patients with pre-dialytic uremia was decreased markedly compared to the normal subjects (p<10−5), but its value in the post-dialytic group tended to recover to the normal value. In conclusion, our studies demonstrate that another possible mechanism of inhibition of the Na+-K+ pump in pre- dialytic uremia might then be a secondary adaptive response of the cell to maintain normal intracellular ion concentration and transmembrane ion gradients in the face of the reduced [Na+]i due to decreased passive Na+ permeability.

show abstract

Erythrocyte and Plasma Lipids in Terminal Renal Insufficiency

Cited by 12 publications

References 6 publications

Uremia and Red Blood Cell Sodium Transport

Uremia and Red Blood Cell Sodium Transport

³¹P NMR spectroscopy of blood plasma: determination and quantification of phospholipid classes in patients with renal cell carcinoma

Erythrocyte Sodium Transport in Dialyzed Uremic Patients

Contact Info

Product

Resources

About

Erythrocyte and Plasma Lipids in Terminal Renal Insufficiency

Cited by 12 publications

References 6 publications

Uremia and Red Blood Cell Sodium Transport

Uremia and Red Blood Cell Sodium Transport

31P NMR spectroscopy of blood plasma: determination and quantification of phospholipid classes in patients with renal cell carcinoma

Erythrocyte Sodium Transport in Dialyzed Uremic Patients

Contact Info

Product

Resources

About

³¹P NMR spectroscopy of blood plasma: determination and quantification of phospholipid classes in patients with renal cell carcinoma