The interaction of enflurane, halothane and the halothane metabolite trifluoroacetic acid with the binding of acidic drugs to human serum albumin. An in vitro study

The interaction of the volatile anaesthetics enflurane, halothane and the halothane metabolite trifluoroacetic acid with the binding of two highly bound acidic drugs (warfarin, phenytoin) to albumin has been studied in vitro by equilibrium dialysis. Trifluoroacetic acid (TFA) inhibited the binding of both drugs to human serum albumin (HSA). Halothane, on the other hand, increased the binding of warfarin to HSA, while enflurane inhibited only the binding of phenytoin. It seems that the binding of the acidic drugs warfarin and phenytoin to HSA is more sensitive to the structures of the gases than for the basic drug diazepam which was previously shown to be equally affected by both gases. Furthermore, it seems that drugs competing for the same binding site (warfarin, phenytoin) may respond differently to conformational changes of the site. It is suggested that drugs bound to the "diazepam site" are more easily affected by the volatile anaesthetics than drugs bound to the "warfarin site".     

Mechanism of altered drug binding to serum proteins in pregnant women: studies with valproic acid

The mechanism underlying the impaired serum protein binding of valproic acid (VPA) in pregnancy was examined in samples collected from 24 healthy women in the last 3 weeks of gestation and 15 age-matched nonpregnant female controls. Experiments were performed in vitro using a rapid equilibrium dialysis technique free from in vitro alterations in free fatty acids (FFA). At a total drug concentration of approximately 420 mumol/L, the free VPA fraction was 10.2 +/- 2.9% (SD) in pregnant women and 4.8 +/- 1.0% in controls (p less than 0.001). Pregnancy was associated with a marked reduction in serum albumin levels but with only a slight, nonsignificant elevation in FFA. Free VPA fraction was negatively correlated with serum albumin levels. A positive correlation between free VPA fraction and FFA was observed in the pregnant group but not in the controls. The only sample collected during labour showed a striking elevation of both free VPA fraction and FFA, in spite of a normal albumin concentration. Scatchard's plots showed VPA bound to two classes of binding sites on the albumin molecule. The number of primary (n1) and secondary (n2) binding sites in pregnant women (n1 = 2.0; n2 = 10.7) was virtually identical to that observed in the controls (n1 = 1.9; n2 = 9.8). The association constants of the primary (k1) and secondary (k2) sites were lower in pregnant women (15.9 X 10(3) and 0.19 X 10(3) L/mol, respectively, vs. 22.6 X 10(3) and 0.33 X 10(3) L/mol in controls) but the difference was not significant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of cosalane--a novel highly lipophilic anti-HIV agent--to albumin and glycoprotein

Cosalane is a potent inhibitor of HIV replication with multiple sites of action. The purposes of this study were to (a) determine the extent and nature of cosalane binding to mucin, alpha(1)-acid glycoprotein (AAG), plasma, and human (HSA) and bovine serum (BSA) albumin, and (b) determine the primary site(s) of cosalane binding to HSA. Plasma protein binding of cosalane was studied by a gel filtration technique. Cosalane binding to HSA was also determined in the presence of salicylic acid. Competitive inhibition studies were conducted using warfarin, digitoxin, and diazepam to determine the primary HSA binding site(s) of cosalane. The drug was bound extensively to HSA and BSA and required 500-550 moles to saturate 1 mole of protein. Stoichiometries of cosalane binding to alpha(1)-acid glycoprotein (AAG) and mucin were between 30 and 50 mol/mol of either glycoprotein. The binding isotherm deviated from a rectangular hyperbola, suggesting self-association of the ligand. Salicylic acid decreased cosalane binding to HSA by one order of magnitude. Inhibition studies of cosalane to HSA revealed that the compound binds primarily to warfarin site with a K(i) of 1.24 +/- 0.24 nM. In summary, cosalane binds extensively to serum albumins and to a lesser extent to both AAG and mucin.     

Use of 1-anilino-8-naphthalene sulfonate as a fluorescent probe in the investigation of drug interactions with human alpha-1-acid glycoprotein and serum albumin

We report a rapid method for the characterization of the human serum albumin (HSA) and alpha-1-acid glycoprotein (AAG) interactions with drugs. The binding of 1-anilino-8-naphthalene sulfonate (ANS) to AAG and HSA was measured by fluorescence spectroscopy. Fluorescence data indicated that ANS was bound tightly to at least one site on AAG, with an affinity constant of 1.35 x 10(6) M-1. The fluorescence of an ANS:AAG complex was quenched by the binding of various drugs. Fluorescence quenching of the HSA:ANS complex showed a single site with an affinity constant of 0.72 x 10(6) M-1. The interaction of AAG and HSA with ANS or other drugs was also studied by comparative equilibrium dialysis. [14C]Pipequaline was used as an AAG and HSA site marker. [14C]Pipequaline seems to share sites I (azapropazone) and II (diazepam and ibuprofen) of HSA. However, high concentrations of warfarin were unable to displace [14C]pipequaline. On the other hand, it was shown that palmitic acid decreased, whereas bilirubin increased the pipequaline binding.     

Protein Binding of Phenprocoumon in the Absence and Presence of Furosemide

Abstract A modification of a fluorometric assay for phenprocoumon is described. The sensitivity of the method has been increased so that the lower limit is 5 ng/ml. By an ultrafiltration technique, phenprocoumon (PPC), in therapeutic concentrations, was bound to the extent of 99.9%, both in undiluted plasma and in Krebs–Henseleit (K–H) solutions containing 4 g human serum albumin (HSA)/100 ml. An increase in the pH from 6.05 to 8.02 in phosphate buffers containing 0.2 g HSA/100 ml yielded an increase in the apparent association constant for PPC binding to HSA from 0.562–10⁶ 1/mol to 1.195–10⁶1/mol, while the number of PPC mol bound per mol albumin remain unchainged (1.05 and 1.03 respectively). A reduced binding of PPC in undiluted plasma containing increasing concentrations of furosemide have been observed. Scatchard plots based on binding studies in K–H solutions containing 0.2 g HSA/100 ml indicate a competitive nature of the albumin binding of PPC and furosemide.     

The binding of colchicine and its derivatives to bovine and human serum albumin and human plasma

The protein binding of colchicine and its derivatives demecolcine and desacetylcolchiceine was studied by equilibrium dialysis at 22 degrees C and pH 7.38 in bovine and human serum albumin and human plasma. Colchicine and demecolcine (2 X 10(-4) -5 X 10(-4) mol/l) is not bound to proteins. The binding of desacetylcholchiceine was 60--80% in the range 10(-4)-5 X 10(-4) mol/l. The association constant for a single binding site was 8.03 X 10(3) 1/mol for human serum albumin and 13.20 X 10(3) 1/mol for human plasma. The binding profiles for desacetylcholchiceine were quite similar in human serum albumin (4% conc.) and human plasma (3.8% conc. of albumin fraction). We suggest that desacetylcolchiceine was likely to be bound predominantly to albumin. Salicylic acid in vitro, at clinical concentrations (1.8--14.5 X 10(-4) mol/l), significantly decreases the binding of desacetylcolchiceine to human serum albumin.     

Protein binding of oxazepam and its glucuronide conjugates to human albumin

The binding of oxazepam and its glucuronide conjugates to human serum albumin (HSA), as well as the binding interactions of the drug and its metabolites, were examined by equilibrium dialysis and kinetic probe studies. Oxazepam and its S(+) glucuronide are bound to the HSA molecule with affinity constants of 3.5 X 10(5) M-1 and 5.5 X 10(4) M-1, respectively, which were independent of protein concentration over a range of 0.1 to 5.0 g/dl. The R(-) glucuronide bound weakly to albumin, with the binding parameter, N X K, increasing at lower albumin concentrations. Pre-acetylation of fatty acid free-HSA resulted in decreased binding of all three compounds, probably by altering the conformation of the binding sites. Kinetic probe studies with p-nitrophenyl acetate indicate that oxazepam and its S(+) glucuronide shared a common binding site on HSA, but that the R(-) glucuronide bound at another site. Oxazepam binding was unaffected by the presence of its glucuronide conjugates but was inhibited by fatty acids. The percentage of oxazepam bound to plasma proteins in patients with renal impairment (94%) was lower than in normal volunteers (97%). This lower binding can neither be attributed to lower albumin concentrations because of the large binding capacity of the protein and linearity of N X K nor to displacement by elevated concentrations of glucuronide conjugates, but it may be ascribed partly to increased plasma fatty acids.     

Spectroscopic techniques in the study of protein binding. A fluorescence technique for the evaluation of the albumin binding and displacement of warfarin and warfarin-alcohol

1. The binding of racemic mixtures of warfarin and warfarin-alcohol to human serum albumin (HSA) is accompanied by an increase in the fluorescence quantum yield of these compounds. This property has been used to measure the characteristics of the binding of warfarin and warfarin-alcohol to HSA at 22 degrees C and 37 degrees C. Within the limits of the technique, no significant differences between the number of binding sites and strength of binding at the tight site at either temperature were observed. 2. The fluorescence of warfarin and warfarin-alcohol was used to label their binding site on HSA and to study the effects of other drugs on their binding. The results indicate that these two molecules are bound to the same site on HSA. 3. The validity of using changes in the fluorescence of warfarin as a measure of its displacement from HSA was investigated. Good correlations were observed between drug-induced decreases in the fluorescence of bound warfarin and displacement as measured by equilibrium dialysis. The displacement of warfarfin, as detected by fluorescence, correlates well with the increase in free warfarin resulting from addition of therapeutic drug concentrations to undiluted human serum. 4. The most potent displacing agents, by all the methods used, were iophenoxic acid, phenylbutazone and oxyphenylbutazone. The first of these is no longer used clinically, but the latter two are and have been reported to cause hypoprothrominaemia by displacing warfarin from HSA. The present study indicates that changes in the fluorescence of warfarin bound to HSA can be used to measure displacement of bound warfarin and to screen drugs that may cause clinically significant interactions by this mechanism.     

Interaction of human serum albumin with furosemide glucuronide: a role of albumin in isomerization, hydrolysis, reversible binding and irreversible binding of a 1-O-acyl glucuronide metabolite

Furosemide 1-O-acyl glucuronide (Fgnd) was reversibly bound to a single class of binding sites on human serum albumin (HSA), and the binding of Fgnd decreased with increasing F concentrations, suggesting that Fgnd binds to the same warfarin binding sites on HSA as F binds. The rate of Fgnd degradation (hydrolysis and acyl migration) decreased in the presence of HSA. Although the formation of acyl migration isomers of Fgnd was slower in the presence of HSA than in its absence, hydrolysis of Fgnd to F was faster in the presence of HSA. Rapid minor irreversible binding of Fgnd to HSA within 30 min was followed by slow major irreversible binding. Slow irreversible binding of Fgnd to HSA was decreased by F, though not significantly. This suggests that major irreversible binding may proceed via reversible binding. It has been reported that acyl migration is a prerequisite for irreversible binding. Therefore, these results indicate that HSA decreases irreversible binding of Fgnd to protein by suppressing acyl migration. Furthermore, these results suggest that HSA may prevent irreversible binding of Fgnd to other proteins in the body by decreasing the concentration of reactive Fgnd in the unbound form. HSA eliminates reactive Fgnd by hydrolysis to F. Therefore, it is concluded that HSA works as a scavenger to decrease reactive compounds by reversible binding or eliminates reactive compounds by irreversible binding.     

Some properties of the interaction between 2,2'-diselenadibenzoic acid and serum albumins

The binding of 2,2'-diselenadibenzoic acid to bovine serum albumin (BSA) and human serum albumin (HSA) was studied by using fluorescence spectroscopy. The measurement was performed in Tris-HCl buffer aqueous medium at pH = 7.40. The quenching constant at 303 K was (3.277 +/- 0.046) x 10(13) L mol(-1) s(-1) for BSA, and (3.946 +/- 0.002) x 10(12) L mol(-1) s(-1) for HSA. Decreased quenching was observed in association with increased temperature. Our findings show that the observed binding constant is dependent on the ionic strength of the medium. It is said that electrostatic interactions play a role in the binding of 2,2'-diselenadibenzoic acid to serum albumin, in addition to the hydrophobic association. The decrease of the linearity of S-V plot demonstrates reduced binding of ligand to the protein in the presence of anionic surfactants such as sodium dodecyl sulfate (SDS), which indicates that 2,2'-diselenadibenzoic acid most likely binds to the hydrophobic pockets within sub-domain IIA of serum albumin, the same site as SDS.     

Binding of clometacin to human serum albumin. Interactions with clofibrate, indomethacin, salicylic acid and warfarin

The binding of clometacin to human serum albumin (HSA) was studied in vitro by equilibrium dialysis. Our results show that binding to HSA is 99% at therapeutic levels. Binding is characterized by several numbers of binding sites (n = 8) with a moderate association constant (K = 2.7 X 10(4) M-1) and by another non-saturable phenomenon (nK = 4200 M-1). Moreover, interactions were studied with many drugs. Clometacin binding was altered by indomethacin, warfarin, chlorophenoxyisobutyrate (CPIB) and salicylic acid (SA). Conversely, clometacin inhibited the binding of these drugs. Finally, all these results were compared with those previously obtained with indomethacin, a positional isomer of clometacin.     

Fluorescence energy transfer study of the relationship between the lone tryptophan residue and drug binding sites in human serum albumin

The relationship between the lone tryptophan residue at position 214 and drug binding sites (Sites I and II) in human serum albumin (HSA) was studied by fluorescence energy transfer. The distance between the lone tryptophan residue and ligands bound to HSA was estimated by F?rster's equation, taking into consideration the degree of ligand binding at these sites, as determined from binding parameters (binding constant, k, and the number of binding sites, n). For all ligands investigated, the distance in each case appeared to asymptotically decrease when the occupation ratio of the binding sites increased with ligand concentration. When the primary binding site of each ligand in HSA was almost saturated, the distance attained a constant value, making possible a somewhat more exact determination of the distance. The distance ranged from approximately 22 to 23 A for ligands typical of Site I (warfarin, dansylamide, dansylglutamine), and approximately 16.1 to 17.5 A for ligands typical of Site II (dansylsarcosine, dansylproline, dansylglycine, diazepam, flufenamic acid).     

Determinants of carbamazepine and carbamazepine 10,11-epoxide binding to serum protein, albumin and alpha 1-acid glycoprotein

The binding of carbamazepine and carbamazepine 10,11-epoxide to serum, albumin and alpha 1-acid glycoprotein (AAG) was determined and compared at drug concentrations ranging from 0.5 to 400 mg/l using equilibrium dialysis and liquid chromatography. The total binding of carbamazepine in serum was determined primarily by albumin and to a lesser extent (20-30%) by AAG. Modified Scatchard plots for carbamazepine binding in serum were biphasic, suggesting the presence of two binding sites on serum protein. Association constants characterizing the first (k1 = 2.4 X 10(4) l/mol) and second (k2 = 4.6 X 10(2) l/mol) binding sites agreed with those measured for AAG and albumin respectively. Modified Scatchard plots for carbamazepine 10,11-epoxide binding in serum were linear and serum binding was largely accounted for by binding to albumin. The epoxide metabolite did not bind to AAG. Carbamazepine binding to AAG was drug concentration-dependent over the concentration range considered to be therapeutic, while the percent binding values for carbamazepine and epoxide binding to albumin and serum from a normal individual were constant over this range. Computer simulations showed that physiological extremes in AAG and albumin concentrations can result in a range of carbamazepine unbound fractions of 0.17 to 0.47. These data suggest that normal variations in concentrations of both proteins may be the principal cause of interpatient variability in serum protein binding of carbamazepine.     

The blood binding of cefotiam and cyclohexanol, metabolites of the prodrug cefotiam hexetil, in-vitro.

The binding of cefotiam and cyclohexanol to human serum, isolated proteins and erythrocytes has been studied in-vitro by equilibrium dialysis. The two molecules are 50% bound to serum proteins and the free fraction for both compounds remained constant within the therapeutic concentration range. Human serum albumin (HSA) was exclusively responsible for the cefotiam binding (48%) with a saturable process characterized by one binding site (n = 1.00 +/- 0.14) with a very weak affinity (Ka = 1457 +/- 352 M-1). Like other cephalosporins, cefotiam showed no binding to alpha 1-acid glycoprotein, lipoproteins or gamma-globulins. Cyclohexanol is mainly bound to HSA with a weak affinity (Ka approximately 1,800 M-1) but lipoproteins and alpha 1-acid glycoprotein bind about 30% of bound cyclohexanol in serum. Interactions with free fatty acids (FFA) or bilirubin were studied at physiopathological concentrations. HSA-bound cefotiam was displaced by FFA (1260 microM) and bilirubin (330 microM), whereas the cyclohexanol binding was inhibited only by FFA. The cefotiam binding site seems to be close to the warfarin site (site I) whereas cyclohexanol probably shares the diazepam site (site II) on HSA. There is no mutual inhibition of binding between cefotiam and cyclohexanol at therapeutic levels. The binding of both compounds to erythrocytes is low and restricted when measured in the presence of plasma.     

Buffer and pH effects on propranolol binding by human albumin and alpha 1-acid glycoprotein

Propranolol binding to isolated human alpha-1-acid glycoprotein (AGP) and human albumin (HSA) was studied by equilibrium dialysis at 37 degrees C. With AGP (0.067%) and HSA (4%), total propranolol concentration was varied from 0.7 to 93,000 ng mL-1. Over this concentration range the percentage drug bound to HSA declined from 49 to 39% while that to AGP declined from 68 to 4%. Two classes of sites were identified on AGP with n1k1 = 8.50 X 10(4) M-1 and n2k2 = 3.12 X 10(4) M-1. With a pH 7.4 phosphate buffer, propranolol binding to AGP was greatest when the protein was initially dissolved in pH 7.4 water compared with pH 7.2 water or the phosphate buffer. Thus, the method of AGP solution preparation affected propranolol binding by this protein. For both AGP and HSA, greater drug binding was noted with phosphate buffers in comparison with a physiological buffer. With phosphate buffers, decreasing pH from 7.4 to 7.0 decreased propranolol binding by AGP, while decreasing pH from 7.7 to 7.4 had little effect. With HSA, the percent propranolol bound consistently decreased on lowering pH from 7.7 to 7.0.     

Plasma protein binding interaction between phenytoin and valproic acid in vitro.

1 Valproic acid or phenytoin were added to fresh human serum in varying concentrations and their binding characteristics determined by the method of Scatchard (1949). 2 Changes in serum albumin binding were investigated for phenytoin in the presence of 280, 560, 1050 and 2100 mumol l-1 valproic acid, and for valproic acid in the presence of 40, 120, 280 and 480 mumol l-1 phenytoin. 3 Phenytoin appeared to bind to a single site on the albumin molecule and could be competitively displaced from this site by concentrations of valproic acid above 280 mumol l-1. 4 At high concentrations of valproic acid, the affinity of phenytoin for albumin was greatly decreased but the number of available binding sites was increased from one to four. 5 Valproic acid was bound to two high affinity and five low affinity binding sites but the latter were not detectable at valproic acid concentrations below 2100 mumol l-1. 6 Phenytoin displaced valproic acid from its high affinity binding sites, although this was statistically significant only at a concentration of 480 mumol l-1 phenytoin.     

Plasma protein binding of the reversible type A MAO inhibitor cimoxatone (MD 780515)

Binding of a new selective reversible type A MAO inhibitor cimoxatone (MD 780515) to plasma proteins was studied in vitro by equilibrium dialysis. Binding to 580 microM human serum albumin (HSA) and to total plasma proteins was 93-96% and independent of cimoxatone concentration (0.15-207 microM). The drug was mainly bound to HSA with two binding sites and a moderate association constant (K = 2.9 X 10(4) M-1). Free fatty acids did not modify cimoxatone binding to HSA. Cimoxatone was also moderately bound to isolated lipoprotein fractions; alpha 1-acid glycoprotein and gamma-globulins did not play an important role in the binding of cimoxatone. MD 770222, the O-demethyl metabolite, appeared to be bound to HSA at the same binding sites as cimoxatone. However, no interaction occurred between the two compounds for 580 microM HSA. L-Tryptophan, bilirubin, the benzodiazepines flunitrazepam and oxazepam, imipramine and aspirin, did not displace cimoxatone from its binding sites. On the other hand, warfarin and phenylbutazone decreased cimoxatone binding to 29 microM HSA but no interaction occurred with 580 microM HSA.     

Diclofenac binding to albumin and lipoproteins in human serum

The binding of diclofenac to human serum albumin (HSA) and to lipoproteins was studied in vitro by equilibrium dialysis. Binding to HSA is characterized by two classes of sites with one site each (K1 = 5 X 10(5) M-1 and K2 = 0.6 X 10(5) M-1). The binding to lipoproteins was shown to be saturable with a larger number of binding sites and low association constants. The evidence of two specific binding sites on HSA was confirmed by circular dichroism data. In addition, an identification of those sites was performed by displacement of fluorescent probes. The data show that the high affinity site (K1 = 5 X 10(5) M-1) is likely to be shared by benzodiazepines while the second one (K2 = 0.6 X 10(5) M-1) is common with the warfarin site.     

Binding of nonsteroidal anti-inflammatory agents and their effect on binding of racemic warfarin and its enantiomers to human serum albumin

The binding of racemic warfarin, its enantiomers, and several nonsteroidal anti-inflammatory agents to human serum albumin was investigated by equilibrium dialysis at 4 degrees C in pH 7.4 phosphate buffer. The primary binding constant for the S(-) enantiomer of warfarin was approximately two times greater than the corresponding binding of the R(+) enantiomer. The effect of azapropazone, phenylbutazone, naproxen, ibuprofen, mefenamic acid, and tolmetin on the binding of racemic warfarin and its enantiomers was studied. Warfarin was displaced by all of the nonsteroidal anti-inflammatory agents except tolmetin. Azapropazone caused the largest displacement of warfarin (39 to 46% free warfarin versus 2.5 to 6% free warfarin without competing drug), followed by phenylbutazone (23 to 43% free warfarin), naproxen (9 to 24% free warfarin), mefenamic acid (5 to 11.5% free warfarin), and ibuprofen (5 to 9% free warfarin). Azapropazone and phenylbutazone competed with warfarin for the same primary binding site on the albumin molecule. Naproxen appeared to affect warfarin binding at both primary and secondary sites. Ibuprofen and mefenamic acid interfered with the binding of warfarin at its secondary sites. In contrast to the other drugs studied, tolmetin caused an increase in the primary binding constant of warfarin. Structural analysis indicated that a common feature of those compounds which primarily bind at the warfarin site is a hydrophobic area bearing a widely delocalized negative charge.     

In vitro binding study of gemfibrozil to human serum proteins and erythrocytes: interactions with other drugs

The binding of gemfibrozil to human serum, isolated proteins and erythrocytes was studied in vitro by equilibrium dialysis. Our results show that this drug is highly bound to serum (99%) at therapeutic levels. Human serum albumin was shown to be mainly responsible for this binding (98.6%) with a saturable process characterized by two binding sites with a moderate affinity. Like many acidic drugs with a carboxylic acidic group, gemfibrozil showed none or negligible binding to alpha 1 acid glycoprotein, lipoproteins and gamma-globulins. The drug binding to erythrocytes is very low (0.8%). The unbound fraction in blood remains constant (0.8%) within the range of therapeutic concentrations. Moreover, interactions were studied with bilirubin and palmitic acid at pathophysiological concentrations and acenocoumarol, salicylic acid, valproic acid, furosemide, phenylbutazone, tolbutamide, warfarin and sulfamethoxazol at therapeutic concentrations. Neither endogenous compounds nor the other drugs studied altered gemfibrozil binding in serum. Likewise, the binding of warfarin to serum and to human serum albumin (600 microM) is not influenced by gemfibrozil.