Plasma protein binding of quinine: binding to human serum albumin, alpha 1-acid glycoprotein and plasma from patients with malaria.

The binding of quinine to human serum albumin (HSA), alpha 1-acid glycoprotein (AAG) and plasma obtained from healthy subjects (10 caucasians and 15 Thais) and from Thai patients with falciparum malaria (n = 20) has been investigated. In healthy volunteers, plasma protein binding expressed as the percentage of unbound quinine was 7.9-31.0% (69-92.1% bound). The mean percentage of unbound quinine found with essentially fatty acid-free HSA (40 g L-1) was 65.4 +/- 1.5% (mean +/- s.d.) and was comparable with the value (66.3 +/- 3.8%, mean +/- s.d.) for Fraction V HSA (40 g L-1). This suggests that fatty acids do not influence the plasma protein binding of quinine. Binding of quinine to 0.7 g L-1 AAG was high (mean unbound 61.0 +/- 5.0%), indicating that quinine is bound primarily to AAG and albumin, although other plasma proteins such as lipoproteins may be involved. The mean percentage of unbound quinine was slightly less in caucasians (14.8 +/- 6.7% unbound), compared with healthy Thai subjects (17.0 +/- 6.7% unbound). The higher binding of quinine in caucasian subjects was associated with a higher plasma AAG concentration observed in caucasians. Mean percentage of unbound quinine was significantly lower in Thai patients with malaria (10.9 +/- 4.0%) than in the healthy Thai subjects. The increase in the extent of quinine binding corresponded with the increase in the acute-phase reactant protein, AAG in the patients with malaria. Overall, when the data were combined there was a significant correlation (r = 0.846, P < 0.005) between the binding ratio (bound/unbound) of quinine and the plasma AAG concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tianeptine binding to human plasma proteins and plasma from patients with hepatic cirrhosis or renal failure.

1. The binding of tianeptine to human plasma, isolated plasma proteins, red blood cells and to plasma from patients with cirrhosis or renal failure was studied in vitro by equilibrium dialysis. 2. Tianeptine is highly bound to plasma (95%) at therapeutic concentrations (0.3-1 microM). No saturation of the binding sites was seen. 3. Human serum albumin (HSA) was shown to be mainly responsible for this binding (94%) with a saturable process characterized by one binding site with a moderate affinity (Ka = 4.2 x 10(4) M-1) and a non-saturable process with a low total affinity (nKa = 1.2 x 10(4) M-1). 4. Like many basic and amphoteric drugs, tianeptine showed a saturable binding to alpha 1-acid glycoprotein (AAG) with one site and a moderate affinity (Ka = 3.7 x 10(4) M-1). Its binding to lipoproteins and red blood cells (RBC) was weak and non-saturable. Over the range of therapeutic drug concentrations (0.3-1 microM), the unbound fraction in blood remains constant (4.5%). 5. Interactions were studied using non-esterified fatty acids (NEFA) at pathological concentrations; they altered tianeptine binding to plasma and to isolated HSA. Tianeptine seems to bind to a HSA site different from sites I (warfarin) and II (diazepam), but close to site II. It also shares the only basic-site on AAG. However, at therapeutic drug concentrations (0.3-1 microM), not all of these interactions occur. 6. The binding of tianeptine varied according to HSA, AAG and NEFA concentrations both in patients and healthy subjects. In patients with chronic renal failure having high NEFA concentrations the unbound fraction of tianeptine (fu) increased from 0.045 to 0.153 compared with normal (P less than 0.001). In cirrhotic patients, with relatively low HSA concentrations, the fu of tianeptine increased from 0.045 to 0.088 compared with normal (P less than 0.01). 7. Multiple regression analysis of all of the data indicated that the fu of tianeptine was related significantly to HSA, NEFA and AAG concentrations, with a particularly strong correlation with NEFA concentrations. Therefore, variation of HSA and NEFA concentrations in patients on maintenance therapy may cause an increase of tianeptine fu.     

Serum binding of indapamide in health and disease: primary role of alpha 1-acid glycoprotein

The serum concentrations of alpha-1-acid glycoprotein (AAG), albumin (HSA), and non-esterified fatty acids (NEFA), and the serum binding of indapamide were measured in four groups of individuals: control (healthy) subjects (N = 24), patients with inflammatory syndrome (N = 28), with hepatic (N = 20) and renal (N = 27) insufficiency. Indapamide serum binding was increased in patients with inflammatory syndrome (82.2 +/- 3.4%, P less than .001), decreased in patients with hepatic insufficiency (72.3 +/- 5.9%, P less than .001) and unchanged in patients with renal insufficiency (77.7 +/- 2.8%) as compared with controls (78.2 +/- 3.1%). A multivariate analysis indicated that these changes were mainly related to concomitant changes in AAG concentration (that explained 63% of intersubject variability in bound/free binding ratio), and to a lesser extent to HSA (that explained only 4% of the variability in the binding). These data show that the free fraction of the acidic drug indapamide in serum is affected by pathologic conditions in which changes in AAG concentration occur and that, unexpectedly, HSA plays a negligible role in the binding.     

The plasma protein binding of metoclopramide in health and renal disease.

The plasma protein binding of metoclopramide was measured after addition of the drug (60 ng ml-1) to plasma from 18 patients with renal disease and 18 age and sex matched healthy individuals. The mean free fraction in renal disease (0.59 range 0.41-0.71) was not significantly different from controls (mean 0.6 range 0.56-0.69). In both groups the binding ratio of metoclopramide was significantly related to plasma alpha 1-acid glycoprotein (AAG) concentration but not to albumin or plasma non-esterified fatty acids concentration. Metoclopramide bound to human serum albumin (HSA) to a limited extent and to human AAG to a greater extent indicating that AAG is the major binding protein for the drug in plasma.     

Prolonged variability in plasma protein binding of disopyramide after acute myocardial infarction.

1 Disopyramide plasma binding was determined in vitro in plasma from 20 patients with acute myocardial infarction (aged 35-79 years) and in 20 age and sex matched healthy subjects. Plasma samples were collected on days 1, 5 and 12 after infarction and when the patient returned to the outpatient clinic. 2 In healthy subjects there was a significant negative correlation between disopyramide free fraction and plasma alpha 1-acid glycoprotein (AAG) concentration. A similar correlation was observed in the patients with myocardial infarction, however this correlation was dependent on time elapsed after infarction. Disopyramide free fraction did not correlate with albumin concentration in either group. 3 Mean plasma AAG concentrations were increased by 63% within 5 days after infarction and had returned to initial levels some months later (73.5 +/- 7.8 days). On each of the four sampling days, a two to four fold individual variability in plasma AAG concentrations was observed. 4 Maximum increases in disopyramide plasma binding were shown on days 5 and 12 after infarction. These increases were dependent on both drug and AAG concentrations. Increases in fraction bound were greater at the higher drug concentrations. Within the usual therapeutic plasma range for disopyramide (2 to 5 mg/l), the mean increases in fraction bound, compared to day 1 data, varied from 22 to 45% respectively. 5 Sequential alteration in AAG concentration after infarction indicates that disopyramide plasma binding may not reach a steady state until some months after infarction. Prediction of the time to achieve this steady state would be difficult due to inter- and intra-patient variability in binding.     

Alpha 1-acid glycoprotein (orosomucoid) and plasma protein binding of quinine in falciparum malaria.

1. Plasma concentrations of alpha 1-acid glycoprotein (AAG) and plasma protein binding of quinine were measured in 97 Thai adults with acute falciparum malaria. There was a linear relationship between log AAG and percentage quinine binding (r = 0.71, P less than 0.001) in vivo, which was similar to that observed in vitro; the slopes and intercepts of the regression lines at AAG concentrations of 1 g l-1 were -8.94 and -8.41, and 7.2% and 10.9%, respectively. 2. Hill plots from these data suggest a single high affinity quinine binding site on each molecule of AAG. 3. Plasma AAG concentrations were consistently raised in acute malaria, and were higher in patients with cerebral malaria [2.03 (0.51) g l-1, mean (s.d.)], and conscious patients with severe malaria [1.93 (0.53) g l-1] than in patients with uncomplicated infections [1.55 (0.58) g l-1], P = 0.008. Plasma protein binding of quinine was correspondingly higher and thus the proportion of free drug was lower in the severe groups; 5.5 (2.4)% compared with 7.2 (1.9)%, P = 0.03. 4. Following recovery from malaria, plasma AAG concentrations fell by an estimated 0.05 g l-1 day-1 to levels that were approximately half (median 45%) the admission value at 28 days. 5. AAG is the principal binding protein for quinine in plasma. Changes in plasma concentrations of this acute phase reactant account for the increased plasma protein binding of quinine in acute malaria.     

Variation in serum binding of tertatolol mediated by disease-induced modification of alpha-acid glycoprotein concentration

Summary The serum concentrations of ₁-acid glycoprotein (AAG), albumin (HSA) and non-esterified fatty acids, and the serum binding of tertatolol were measured in four groups of individuals: healthy control subjects (n=24), and patients with inflammation (n=28), and hepatic (n=20) and renal (n=27) insufficiency.Serum binding of tertatolol was increased in patients with inflammation (94.6%), decreased in patients with hepatic insufficiency (88.8%) and it was unchanged in patients with renal insufficiency (92.8%) as compared to controls (92.7%).Multivariate analysis indicated that the changes were mainly related to concomitant changes in AAG concentration, which could account for 57% of intersubject variability in the bound/free ratio, and to a lesser extent in HSA, which accounted for only 4% of the variability in the binding.The data show that the free fraction of the basic drug tertatolol in serum is affected by pathological conditions that cause changes in AAG concentration.     

Protein binding predictions in infants

Plasma binding protein levels are lower in the newborn than in the adult and gradually increase with age. At birth, human serum albumin (HSA) concentrations are close to adult levels (75%–80%), while alpha 1-acid glycoprotein (AAG) is initially half the adult concentration. As a result, the extent of drug binding to HSA is closer to that of the adult than are those drugs bound largely to AAG. A model that incorporates the fraction unbound in adults and the ratio of the binding protein concentration between infants and adults successfully predicted the fraction unbound in infants and children.     

Influence of plasma protein binding on the brain uptake of an antifungal agent, terbinafine, in rats

The intracarotid injection technique has been used to determine the unidirectional brain uptake of an antifungal, lipophilic agent, terbinafine (Lamisil, Sandoz Basle), in the rat. Ultrafiltration showed it to be highly bound to human plasma, human serum albumin (HSA), alpha 1-acid glycoprotein (AAG) and lipoproteins (VLDL, LDL, HDL). The effect of plasma protein binding of the drug on brain uptake was also examined with the technique. The lowest brain uptake was observed in the presence of plasma (6%); it varied from 23 to 30% with physiological concentrations of VLDL, LDL and HSA and was significantly higher (43-45%) in the presence of physiological concentrations of AAG and HDL. The free fraction as determined in-vitro and the brain uptake of the drug varied inversely with the plasma protein concentrations; however, the brain uptake was higher than expected from in-vitro measurements. These data indicate that the amount of circulating Lamisil available for brain penetration exceeds its free fraction; they also show that plasma proteins differently reduce the brain transport of the drug.     

Differential protein binding of indinavir and saquinavir in matched maternal and umbilical cord plasma

AIMS: To determine whether lower umbilical cord than maternal binding of indinavir and saquinavir contributed to the low cord : maternal (C : M) total concentration ratios reported previously. METHODS: Indinavir and saquinavir unbound fraction (fu) was determined using equilibrium dialysis. Buffer solutions of human serum albumin (HSA) (20.0, 30.0, 40.0 g l(-1)) and alpha(1)-acid glycoprotein (AAG) (0.20, 0.60, 2.00 g l(-1)) were spiked with indinavir (1.00 and 8.00 mg l(-1)) or saquinavir (0.15 and 1.50 mg l(-1)). Matched maternal and umbilical cord plasma was spiked with 1.00 mg l(-1) indinavir (n = 12) or 0.15 mg l(-1) saquinavir (n = 20). Spiked protein/plasma solutions were dialyzed against isotonic phosphate buffer, at 37 degrees C. At equilibrium, indinavir and saquinavir concentrations were quantified, and the f(u) determined. RESULTS: Indinavir and saquinavir demonstrated protein concentration-dependent binding in buffer solutions of HSA and AAG. Indinavir f(u) was significantly higher in umbilical cord (0.53 +/- 0.12) compared with maternal (0.36 +/- 0.11) plasma (95% CI of the difference -0.26, -0.097). Similarly, saquinavir fu was different between umbilical cord (0.0090 +/- 0.0046) and maternal plasma (0.0066 +/- 0.0039) (95% CI of the difference -0.0032, -0.0016). The transplacental AAG concentration gradient contributed significantly to the binding differential of both drugs. CONCLUSIONS: The differential plasma binding of both drugs, which was largely the result of the transplacental AAG concentration gradient, would contribute to the low C : M total plasma concentration ratios observed previously. Unbound concentrations of indinavir and saquinavir are likely to be substantially lower in umbilical cord than maternal plasma.     

Plasma protein binding of catecholamines,prazosin and propranolol in diabetes mellitus

Summary In the present study equilibrium dialysis has been used to determine the degree of protein binding of the catecholamines adrenaline and noradrenalin and the adrenergic receptor blockers, prazosin and propranolol in diabetics. The binding of the catecholamines in plasma from Type I and II diabetic patients was not significantly different from that of healthy subjects. The ratio of the bound and free catecholamine concentrations was correlated with the level of albumin (HSA). Significantly reduced protein binding of prazosin was observed in Type I and II diabetic subjects compared to healthy volunteers. The binding of propranolol was significantly reduced in Type I patients. The ratios between the bound and unbound concentrations of prazosin and propranolol were significantly correlated with the levels of a,-acid glycoprotein (AAG). The results suggest that non-enzymatic glycosylation of plasma proteins may increase the unbound fraction of the adrenergic blockers prazosin and propranolol.     

Effect of chronic renal failure on the disposition of highly hepatically metabolized drugs

OBJECTIVE: The objective of this study was to investigate the effect of renal impairment on the disposition of an extensively metabolized drug, i.e., drug X. Drug X has a hepatic extraction ratio of less than 0.1 and free fraction in plasma of less than 1% in healthy volunteers. METHODS: Pharmacokinetic (PK) parameters of drug X were obtained from subjects with normal renal function (I, n = 6), as well as in subjects with mild (II, n = 5), moderate (III, n = 7) and severe renal impairment (IV, n = 5). Disease-PK models were developed to describe the changes of PK parameters with respect to renal function measured by creatinine clearance. While experimentally observed data are presented for drug X, additional simulations were performed for other drugs that are extensively metabolized (extensive metabolism is defined as metabolism that accounts for more than 90% of total drug elimination). The simulated scenarios included drugs that have a low extraction ratio (ER) and with high plasma protein binding (PPB), low ER and with low PPB, high ER and with high PPB, or high ER and with low PPB. RESULTS: Systemic clearance of drug X, a low ER and high PPB drug, in renal patients depended on the simultaneous effects of renal disease on protein binding and intrinsic metabolic clearance. Protein binding of drug X was related to creatinine clearance in an inverse hyperbolic relationship, while the unbound intrinsic metabolic clearance declined linearly with creatinine clearance. Because the disease effects on these two factors offset each other in terms of total systemic clearance, the lowest total systemic clearance was not observed in the severely renal impairment patients, but rather in the moderately impaired group. Additional simulations showed that for low ER drugs that are highly metabolized, the pattern and magnitude of systemic clearance change in renal patients depended on how the disease affected PPB and/or intrinsic metabolic clearance. But the systemic clearance of high ER drugs would not be as susceptible to the effect of renal disease as that of low ER drug. CONCLUSIONS: Chronic renal disease should not be considered as an isolated event that affects only renally excreted drugs. Uremia may also modify the disposition of a highly metabolized drug by changes in plasma protein binding and/or hepatic metabolism.     

Determinants of the plasma protein binding of theophylline in health.

1 The plasma protein binding of theophylline was determined after addition of [14C]-theophylline (15 micrograms/ml) to plasma from 24 healthy drug-free volunteers and equilibrium dialysis for 2 h at 37 degrees C. 2 The percentage of drug unbound was 60.0% +/- 2.2% (s.d.) with very little variation between individuals. The binding ratio of theophylline was not significantly related to the plasma albumin or alpha 1-acid glycoprotein (AAG) concentrations but was significantly, although weakly, negatively related to the logarithm of the non-esterified fatty acid concentration (NEFA) (r = 0.443, P less than 0.05). 3 Intravenous administration of heparin (1000 units) caused a significant rise in plasma NEFA concentration and in the percentage of drug unbound in plasma after equilibrium dialysis. 4 In human serum albumin solutions, the binding ratio of theophylline was significantly related to the albumin concentration and at the albumin concentration seen in the 24 normal subjects, the percentage of drug unbound was almost identical. Addition of AAG in physiological concentrations did not enhance theophylline binding but oleic acid, and to a lesser extent palmitic acid, reduced binding significantly. 5 The percentage of theophylline unbound in plasma varied markedly with pH so that at pH7 the percentage unbound was 52% greater than at pH 8. There was no evidence of concentration dependence of binding up to 140 micrograms/ml theophylline. 6 Theophylline appears to bind almost exclusively to albumin and its plasma protein binding varies little in healthy subjects, showing no concentration-dependence over the therapeutic range of concentrations. The binding is affected by pH and by NEFA concentration, however, and these factors may be of greater importance in disease states. Caution should be employed in the use of heparin in studies of plasma protein binding of theophylline.     

Factors influencing the protein binding of a new phosphodiesterase V inhibitor, DA-8159, using an equilibrium dialysis technique

Various factors influencing the protein binding of DA-8159 to 4% human serum albumin (HSA) were evaluated using an equilibrium dialysis technique at an initial DA-8159 concentration of 5 microg/mL. It took approximately 8 h incubation to reach an equilibrium between 4% HSA and an isotonic phosphate buffer of pH 7.4 containing 3% of dextran ('the buffer') using a Spectra/Por 2 membrane (mol. wt. cut-off: 12,000--14,000) in a water bath shaker kept at 37 degrees C and at a rate of 50 oscillations per min. The extent of binding was dependent on DA-8159 concentrations, HSA concentrations, incubation temperature, buffer pH, and alpha-1-acid glycoprotein (AAG) concentrations. The binding of DA-8159 in heparinized human plasma (93.9%) was significantly higher than in rats (81.4%), rabbits (80.4%), and dogs (82.2%), and this could be due to differences in AAG concentrations in plasma.     

Differences in the serum binding determinants of isradipine and darodipine--consequences for serum protein binding in various diseases.

1. Serum protein binding of isradipine and darodipine, and serum concentrations of alpha 1-acid glycoprotein (AAG), albumin (HSA) and non-esterified fatty acids (NEFA) were measured in three groups of patients, I: healthy subjects (n = 20); II: patients with inflammatory disorders (n = 15) and III: patients with hepatic insufficiency (n = 17). 2. AAG was increased significantly in group II patients (P less than 0.001) and decreased in group III patients (P less than 0.001); HSA was decreased significantly in group II and group III patients (P less than 0.001). 3. The free percentage of isradipine was decreased significantly in group II patients (P less than 0.05) and increased in group III patients (P less than 0.05) and multivariate analysis showed that these variations were inversely related to changes in AAG concentration. 4. The free percentage of darodipine was increased significantly in group II and III patients (P less than 0.05) due to a decrease in HSA concentration, as shown by multivariate analysis. 5. The changes in free serum percentages of isradipine and darodipine were inversely related to concomitant changes in the concentration of the serum protein for which they showed the highest affinity, AAG for isradipine and HSA for darodipine, respectively. 6. The unexplained variability in the binding data was greater when AAG was the major determinant of binding (isradipine).     

Predicting Drug Binding to Human Serum Albumin and Alpha One Acid Glycoprotein in Diseased and Age Patient Populations

Plasma protein binding, namely the fraction unbound (f_u), can be an important determinant of the disposition and response of drugs. The primary objective of this study was to predict f_u values of 183 drugs utilizing either a single binding protein model, where the predominant binding protein had been established, or a multiple binding protein model (MBPM), where the relative binding contribution of human serum albumin (HSA) or alpha 1 acid glycoprotein (AAG) is known. Mean protein concentrations, dependent on disease or age, were used to account for changes in f_u. A simple scaling approach for binding protein concentration was employed to account for quantitative changes in molar concentrations of either HSA or AAG in their respective conditions. The MBPM predictive model works best if the relative binding contribution of HSA and AAG is known, and a scaler for the change in protein concentration can be adjusted accordingly. The value of MBPM was most evident when considering reported changes in lidocaine binding because of increasing AAG concentration in response to trauma. The present approach enhances the ability to predict f_u in diseased and age populations because of quantitative changes in major binding proteins.     

Factors influencing the protein binding of vancomycin.

Various factors influencing the protein binding of vancomycin were examined using equilibrium dialysis method. Four per cent human serum albumin (HSA) and/or 0.08 per cent alpha-1-acid glycoprotein (AAG), dissolved in isotonic phosphate buffer, were dialyzed against isotonic phosphate buffer of pH 7.4 using Spectrapor 2 membrane. The protein binding of vancomycin to 0.08 per cent AAG was dependent on vancomycin concentrations; the values ranged from 21.1 per cent at the vancomycin concentration of 20 micrograms ml-1 to 5.30 per cent at 2400 micrograms ml-1. However, binding to 4 per cent HSA was relatively constant, 8.79 +/- 2.43 per cent over a vancomycin concentration range of 20-2400 micrograms ml-1. The values to 4 per cent HSA alone and 0.08 per cent AAG alone did not predict the greater binding of vancomycin in the presence of both proteins, especially at higher concentrations of vancomycin; the values to 4 per cent HSA with 0.08 per cent AAG were constant, 26.3 +/- 3.74 per cent, at the vancomycin concentration range of 20-2400 micrograms ml-1. This suggested an interaction between the proteins, which resulted in enhanced binding of vancomycin. The protein binding of vancomycin to 4 per cent HSA with 0.08 per cent AAG was not influenced by the different incubation temperatures (4 degrees, 22 degrees, and 37 degrees), quantities of heparin (up to 40 units ml-1) or AAG (up to 0.16 per cent), or buffers (isotonic phosphate buffer of pH 7.4, phosphate buffer of pH 7.4 and 0.9 per cent NaCl solution) at the vancomycin concentration of 80 micrograms ml-1. Vancomycin was found to be stable in human serum albumin or in isotonic phosphate buffer of pH 7.4.     

Protein-Binding Characteristics of Voriconazole Determined by High-Throughput Equilibrium Dialysis

Plasma protein binding (PPB) can possibly alter the already variable pharmacokinetics of voriconazole. Voriconazole PPB was determined only once, being 58%, according to equilibrium dialysis (ED). We investigated voriconazole PPB more in detail, with a convenient and newer high-throughput ED assay (HT-ED), in human blank plasma spiked with voriconazole and in plasma from intensive care unit (ICU) patients treated with voriconazole. HT-ED was conducted in a 96-well plate, setup against phosphate-buffered saline. Voriconazole concentrations were measured by liquid chromatography–tandem mass spectrometry. The median PPB was 47.6% [interquartile range (IQR) 45.3%–50%] in vitro, and 49.6% (IQR 42.5%–52.5%) in ICU samples (p = 0.35), and is not depending on total voriconazole concentration (0.7–11.2 mg/L, p = 0.65). The drug mainly binds to albumin (25.5 ± 5.1%), and to a lesser extent to α-1-acid glycoprotein (AAG; 4.8 ± 1.2%). The HT-ED assay can be performed at 37°C or 25°C (p = 0.44) and in batch: PPB variations during freeze–thaw cycles (p = 0.13) and during frozen storage up to 12 months (p = 0.10) were not clinically relevant. Voriconazole PPB is approximately 50%, according to HT-ED. As albumin and AAG only account for approximately 30% of total voriconazole PPB, other plasma components could influence PPB and therefore efficacy or toxicity because of variations in unbound fractions. © 2014 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 103:2565–2570, 2014     

The effects of age and smoking on the plasma protein binding of lignocaine and diazepam.

In 63 healthy ambulant subjects 18 to 88 years of age, the plasma protein binding of diazepam (principally bound to albumin) decreased with age. Diazepam binding in plasma correlated positively with plasma albumin concentration which also decreased with age. In contrast, the plasma protein binding of the basic drug, lignocaine (predominantly bound to alpha 1-acid glycoprotein [AAG]), tended to increase slightly with age. Lignocaine binding in plasma correlated positively with plasma AAG concentration which also increased slightly with age. Smoking did not affect the plasma protein binding of diazepam or lignocaine or the plasma concentrations of albumin, AAG or nonesterified fatty acids. These results suggest that age-related changes in plasma protein binding of lignocaine and diazepam are determined in part by age-related changes in the concentrations of the binding proteins in plasma. The ageing process alone causes only small changes in the plasma protein binding of these drugs compared with the effect of disease states, however.