Drug protein binding in chronic renal failure: Evaluation of nine drugs

Drug protein binding in chronic renal failure: Evaluation of nine drugs. In this study, changes of protein binding of nine drugs were evaluated. In addition, theophylline and phenytoin, the two drugs with the most substantial and progressive decrease in protein binding, were further studied by high performance liquid chromatography (HPLC)-fractions of ultrafiltrate of normal and uremic serum, in an attempt to identify substances causing drug protein binding inhibition. There was a marked decline of the protein binding of theophylline, phenytoin and methotrexate (dialyzed patients vs. normals: -20.1, -16.0 and -15.1%, respectively). There was a rise in the protein binding of propranolol, cimetidine and clonidine. The changes observed for diazepam, prazosin and imipramine were less marked. For phenytoin, theophylline, methotrexate and diazepam, protein binding was inversely correlated to the serum creatinine (r = 0.87, 0.80, 0.79 and 0.67, P < 0.001), and a less pronounced but still significant positive correlation was found for clonidine (r = 0.46, P < 0.01). Ultrafiltrate, obtained during a hemofiltration session, inhibited protein binding of theophylline and phenytoin in a dose dependent way. After separation of this ultrafiltrate by HPLC, it appeared that for both theophylline and phenytoin at least a part of this inhibitory activity corresponded to the elution zone of hippuric acid. For theophylline two other inhibitory zones were further recognized: one corresponding to the elution zone of NaCl and one in which the responsible substance remained unidentified. Hippuric acid in solution inhibited protein binding of theophylline and phenytoin in a dose dependent way. In conclusion, protein binding of several drugs currently used in renal failure is affected in parallel with renal function, which might affect the therapeutic effectiveness of the drugs. Furthermore, hippuric acid appears to play an important role in the defect of the protein binding of theophylline and phenytoin

HPLC fractions of human uremic plasma inhibit the RBC membrane calcium pump

HPLC fractions of human uremic plasma inhibit the RBC membrane calcium pump. We have reported that uremic plasma filtrates (UF) inhibit the red blood cell (RBC) membrane calcium pump. The inhibitor was dialyzable, smaller than 3,000 molecular weight, heat-stable, and protease-resistant. In the present study, we used reverse-phase preparative HPLC, analytical HPLC, and Sephadex G-25 elution to identify inhibitory fractions. Inhibition was confirmed in three different bioassays: (1) Sr2+ efflux in intact RBC, the primary bio-assay; (2) 45Ca efflux in intact RBC; and (3) calcium ATPase activity in isolated RBC membranes. Active fractions were analyzed by mass spectrometry, capillary electrophoresis, enzymatic analysis, gas chromatography-mass spectrometry, and nuclear magnetic resonance spectroscopy. These demonstrated a number of compounds, including: sugars, polyols, osmolytes like betaine and myoinositol, amino acids, and other metabolites, such as 3-D-hydroxybutyrate, dimethylgly-cine, trimethylamine-N-oxide, guanidinoacetic acid and glycine. Many individual compounds were then tested for an effect on the calcium pump. Thus, HPLC was able to separate a substantial number of compounds in inhibitory fractions. Efforts are under way for precise identification of the inhibitor, to advance our understanding of uremic toxicity and/or hypertension in CRF

An update on uremic toxins

The general and non-specific treatment of uremic intoxication by dialysis or transplantation had a more successful evolution in recent decades than the basic in-depth biochemical investigation of uremic toxicity. Symposia like the present one are, however, milestones on the road to a better knowledge of uremic toxicity and its treatment. Trends can be recognized in the description of the clinical state of uremia, in the methodology used to isolate, purify and identify uremic toxins, in the importance attached to a single toxin, in the inhibitory impact of toxins on enzymes or receptors, and in the experimental reproduction of specific toxic effects

CEFODIZIME - ENHANCEMENT OF DEPRESSED PHAGOCYTOSIS-ASSOCIATED RESPIRATORY BURST ACTIVITY IN CHRONIC UREMIC PATIENTS.

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