Lignocaine disposition in blood in epilepsy.

1 The plasma concentration of alpha 1-acid glycoprotein (AAG) was significantly greater in 27 epileptic subjects receiving anticonvulsants compared with 27 age- and sex-matched drug-free control subjects. 2 Increased AAG concentration was associated with enhanced lignocaine binding in the plasma of epileptics. 3 Increased AAG concentration was also associated with a redistribution of lignocaine out of red cells and into plasma thus lowering the blood to plasma concentration ratio. 4 Enhanced lignocaine binding in epileptics receiving anticonvulsant therapy may result in lower free (unbound) plasma concentrations of the drug compared to normal subjects with equivalent total plasma lignocaine concentrations.     

Binding of gefitinib, an inhibitor of epidermal growth factor receptor-tyrosine kinase, to plasma proteins and blood cells: in vitro and in cancer patients

Summary Gefitinib exhibits wide inter-subject pharmacokinetic variability which may contribute to differences in treatment outcome. Unbound drug concentrations are believed to be more relevant to pharmacological and toxicological responses than total drug. Thus it is desirable to determine gefitinib binding in plasma and factors affecting this process. An equilibrium dialysis method using 96-well microdialysis plates was optimized and validated for determining the fraction unbound (fu) gefitinib in human plasma. Gefitinib binding in plasma from four different species and isolated protein solutions as well as drug partitioning in human blood cells were investigated. Unbound gefitinib plasma concentrations were measured in 21 cancer patients receiving daily oral gefitinib 250 mg or 500 mg. It was found that gefitinib was extensively bound in human rat mouse and dog plasma with mean fu values of 3.4%, 3.8%, 5.1% and 6.0% respectively. In isolated protein solutions approximately 90% and 78% of gefitinib was bound to human serum albumin (HSA) (40 mg/dL) and alpha1-acid glycoprotein (AAG) (1.4 mg/dL) with binding constants of 1.85 × 10⁴ M⁻¹ and 1.13 × 10⁵ M⁻¹ respectively. In whole blood 2.8% of gefitinib existed as the free drug while 79.4% and 17.8% was bound to plasma proteins and blood cells respectively. In plasma from cancer patients fu at pre-treatment varied 2.4-fold (mean 3.4 ± 0.6%; range 2.2–5.4%) and fu was constant over the 28-days of treatment (P > 0.05). Pre-treatment AAG concentration was negatively correlated with pre-treatment fu (R² = 0.28, P = 0.01). In conclusion gefitinib is highly protein bound (∼ 97%) in human plasma. Variable AAG concentrations observed in cancer patients may affect gefitinib fu with implications for inter-subject variation in drug toxicity and response.     

On the role of alpha 1-acid glycoprotein in lignocaine accumulation following myocardial infarction.

1 Blood plasma and free lignocaine concentrations have been measured 12 h after beginning a constant infusion of 2 mg/min and again at the end of the infusion (36-72 h) in five patients with myocardial infarction (MI) and compared with five control patients who did not develop objective evidence of MI. 2 In MI patients, total plasma concentration rose significantly between 12 h and the end of infusion. Because of an increase in alpha 1 acid glycoprotein (AAG) plasma binding increased, so that free drug concentration did not change. The rise in whole blood concentration was less than that in plasma as a result of drug redistribution out of red cells due to enhanced binding. 3 In control patients, neither blood nor plasma concentrations changed with time and plasma binding remained constant. Free drug concentrations, however, rose slightly. 4 The concentrations of GX and MEGX remained unchanged in all patients, but the ratio of lignocaine/MEGX concentrations fell in controls but rose in MI patients. 5 Pharmacokinetic modelling suggested that at least some of the rise in blood lignocaine concentration was due to reduced clearance resulting from enhanced plasma binding. 6 We conclude that the rise in AAG following MI is responsible for increased plasma binding and drug redistribution within blood. These changes, together with a reduction in lignocaine clearance, can explain much of the phenomenon of lignocaine accumulation in MI.     

Relationship between alpha 1-acid glycoprotein and plasma binding of disopyramide and mono-N-dealkyldisopyramide.

Highly purified serum albumin did not bind either disopyramide (DP) or mono-N-dealkyldisopyramide (MND). The unbound fraction of DP and MND in highly purified serum alpha 1-acid glycoprotein (AAG) at 0.5 g/l was 57 and 62 and at 2.0 g/l 19 and 30% respectively. Unbound DP and MND were measured in spiked plasma (10 mumol/l of DP or MND), from 60 patients, having AAG concentrations varying from 0.4 to 3.0 g/l. Unbound drug varied from 13 to 58 and from 24 to 62% for DP and MND, respectively, and was inversely related to the plasma concentration of AAG (r = -0.9016, r = -0.9157). A linear relationship was found between the binding ratio (moles bound divided by moles unbound) and the plasma concentration of AAG for both DP (r = 0.9199) and MND (r = 0.9270), whereas no relationship was found between the binding ratios of DP or MND and the plasma concentrations of total protein, albumin, haptoglobin, alpha 1-antitrypsin or the immunoglobulins IgG, IgA or IgM. In patients on DP maintenance therapy, a linear relationship was found between percent unbound DP and the plasma concentration of DP in samples with similar AAG concentrations. Furthermore, a linear relationship was found between the binding ratio of DP and the plasma concentration of AAG in samples with similar DP concentrations. The present findings support the concept that AAG is the major serum protein responsible for the binding of DP and MND.     

The plasma protein binding of basic drugs.

The plasma protein binding of basic drugs appears to vary more than was at first assumed and is related to the marked intra-and interindividual differences in one of the chief binding proteins, AAG. Changes in AAG concentrations will result in alterations in the distribution and metabolism of basic drugs which will complicate the interpretation of the relationship between total drug concentration and drug efficacy or toxicity. For some drugs, e.g. lignocaine, direct measurement of free concentrations may improve their clinical use but rapid and reliable techniques are as yet not readily available.     

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.     

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.     

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.     

Should we routinely measure free plasma phenytoin concentration?

The plasma protein binding of phenytoin was investigated in 56 epileptic patients attending the outpatient clinic. The free phenytoin fraction was measured by equilibrium dialysis at 37 degrees C and the total concentration by a homogenous enzyme immunoassay technique. The free fraction ranged from 0.123 to 0.177 (median 0.144, mean +/- s.d. = 0.145 +/- 0.12). Distribution was consistent with normality. Four of the patients were also taking sodium valproate. The median free fraction of phenytoin in these patients was 0.174, 21% higher than that of the total group (P less than 0.05). The total concentration of phenytoin varied from 0.3 to 29.4 micrograms/ml (median 12 micrograms/ml, mean +/- s.d. = 13.31 +/- 6.13 micrograms/ml) and the free fraction was not related to the total drug concentration. There was a highly significant relationship between free phenytoin concentration and total phenytoin concentration (r = 0.986, P less than 0.001). There appears to be very little variability in protein binding of phenytoin in epileptic patients and thus total plasma phenytoin concentration closely reflects the free (unbound) drug concentration. Routine estimation of free plasma phenytoin concentration is therefore unnecessary and should be reserved for those patients where alteration in binding is likely, e.g. renal or hepatic disease or where adverse effects occur at unexpectedly low total phenytoin concentrations.     

Relationship between alpha 1-acid glycoprotein and distribution of disopyramide and mono-N-dealkyldisopyramide in whole blood.

The binding of disopyramide (DP) and mono-N-dealkyldisopyramide (MND) was measured by equilibrium dialysis in spiked whole blood (10 mumol l-1 DP or MND) from 50 patients having a serum concentration of alpha 1-acid glycoprotein (AAG) ranging from 0.40 to 3.14 g l-1, as well as in whole blood from five healthy subjects, spiked with different concentrations of AAG ranging from 0.61 to 3.33 g l-1. The binding ratio (moles bound divided by moles unbound) in all samples increased from 1.0 to 8.0 for DP and 0.6 to 3.3 for MND with increasing AAG concentrations. The binding varied according to the AAG concentrations both in patients and healthy subjects. Similarly total and free plasma concentrations of DP and MND were also measured. With increasing AAG concentrations the total concentrations measured increased from 9.0 to 15.9 mumol l-1 for DP and from 6.8 to 11.8 mumol l-1 for MND whereas the free concentrations decreased from 3.8 to 0.5 mumol l-1 for DP and from 5.0 to 2.0 mumol l-1 for MND. With increasing AAG concentrations the whole blood/plasma concentration ratio decreased from 1.11 and 1.47 to 0.63 and 0.85 for DP and MND respectively. The ratio between their concentration in cells and the unbound concentration in plasma, however, was constant over the whole AAG concentration range. The mean ratios for all samples were 3.0 and 3.1 for DP and MND respectively, indicating that both compounds are bound or distributed to the blood cells. The distribution of the drugs in whole blood changed according to increasing AAG concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of plasma alpha1-acid glycoprotein concentration on the accumulation of lidocaine metabolites during continuous epidural anesthesia in infants and children.

OBJECTIVE: Alpha1-acid glycoprotein (AAG) is an acute-phase protein that is responsible for binding basic drugs such as lidocaine (LDC). The effect of AAG on the duration of LDC during continuous epidural anesthesia in infants and young children was investigated. PATIENTS, MATERIALS AND METHODS: Plasma levels of LDC and its active metabolites, monoethylglycinexylidide (MEGX) and glycinexylidide (GX), were monitored in 20 infants and children, 5 months to 6 years of age, who received continuous epidural infusion of 2.5 mg kg(-1) LDC hourly during abdominal or thoracic surgeries. RESULTS: Plasma LDC concentrations were constant after the first hour of injection. In contrast, the concentrations of MEGX and GX increased continuously during epidural infusion in all patients. The plasma AAG concentration correlated significantly (r = 0.814, p<0.001) with the steady-state LDC level. In addition, significant inverse correlation was observed between the plasma AAG concentration and the accumulation rate of MEGX (r = 0.742, p = 0.002). The plasma AAG concentration and the accumulation rate of GX correlated weakly (r = 0.474, p = 0.035). There was no correlation between the age of the patient and the plasma AAG concentrations (r = 0.295, p = 0.206). CONCLUSION: Our results suggest that the plasma AAG concentration is a valuable index in preventing the toxicity caused by accumulation of MEGX during continuous epidural anesthesia of LDC.     

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.     

Plasma protein-binding and CSF concentrations of valproic acid in man following acute oral dosing

Simultaneous cerebrospinal fluid (CSF), total and free plasma valproic acid (VPA) concentrations were measured in 17 patients receiving two weight-adjusted VPA doses as seizure prophylaxis prior to diagnostic myelography or cisternography. Free drug concentrations were similar when measured by equilibrium dialysis (ED) at 37 degrees C for 24 h (Dianorm) or by a novel ultrafiltration (UF) method (EMIT freelevel system 1, SYVA) (ED:2.3-35.5 mg-1; UF:1.3-33.6 mg-1; r = 0.78, P less than 0.002). There was wide variation in total VPA concentration (39-154 mg-1) and in free fraction (ED: 3.3-25.6%; UF: 5.9-24%). Concentration dependent protein binding was not demonstrated. CSF VPA varied between 4.2 and 25.6 mg-1 and was accurately reflected by free plasma VPA concentrations (ED: r = 0.75, P less than 0.005: UF: r = 0.93, P less than 0.001). CSF concentration also correlated with the total plasma VPA (r = 0.76, P less than 0.005). The Emit freelevel system 1 provides a rapid measure of unbound VPA in the plasma which may be suitable for routine clinical use.     

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.     

Stereoselective binding of propranolol in the elderly.

The influence of age on the stereoselective serum protein binding of propranolol was investigated. Serum was obtained from 10 young (mean age 23 +/- 2 years) and ten elderly (mean age 68 +/- 2 years) healthy male volunteers. The free fraction of propranolol (fu) was measured by equilibrium dialysis, using tritium labeled (+/-)- and (-)-propranolol. The fu values were 0.159 +/- 0.049 and 0.148 +/- 0.028 (+/-), 0.135 +/- 0.041 and 0.136 +/- 0.04 (-), 0.174 +/- 0.056 and 0.161 +/- 0.028 (+) in the young and elderly subjects, respectively. Serum alpha 1-acid glycoprotein (AAG) concentrations were 81.4 +/- 33.0 and 81.0 +/- 21.6 mg 100 ml-1 in young and elderly respectively (P greater than 0.05). Variability in AAG concentration accounted for most of the observed intersubject variability in the binding of both propranolol isomers. The stereoselective binding of propranolol does not appear to be affected by age.     

Monitoring of free plasma propranolol

Evidence exists that the free plasma propranolol concentration may correlate with the pharmacological effect in a better way than the total plasma concentration. Three approaches to obtain the free fraction were compared,viz. 1) equilibrium dialysis, 2) calculation from the ratio erythrocyte concentration: plasma concentration ([R]/[P]-ratio) and 3) derivation from the salivary concentration. It is concluded that the [R]/[P]-ratio has a linear relationship to the free propranolol concentration, described by the equation [R]/[P]=6.9 (1-f)−0.25 (n= 46, r=+0.956; p<0.01). This method is reliable and simple to perform. No differences were seen between fresh blood samples, 14 days oldAcd-blood or artificial blood. The presence of various other drugs (4-hydroxypropranolol, chlorthalidone, clonidine, K-canrenoate, hydrallazine) did not interfere with the relationship between [R]/[P] and (1-f). A constant relationship between the salivary and free plasma propranolol concentrations does not exist, mainly because of buccal contamination. Equilibrium dialysis may pose an analytical problem. Therefore, the authors prefer the method based on the [R]/[P]versus (1-f) relationship.     

Measurement of fraction unbound paclitaxel in human plasma.

The clinical pharmacokinetic behavior of paclitaxel (Taxol) is distinctly nonlinear, with disproportional increases in systemic exposure with an increase in dose. We have recently shown that Cremophor EL, the formulation vehicle used for i.v. administration of paclitaxel, alters drug distribution as a result of micellar entrapment of paclitaxel, and we speculated that the free drug fraction (fu) is dependent on dose and time-varying concentrations of Cremophor EL in the central plasma compartment. To test this hypothesis, a reproducible equilibrium dialysis method has been developed for the measurement of paclitaxel fu in plasma. Equilibrium dialysis was performed at 37 degrees C in a humidified atmosphere of 5% CO(2) using 2.0-ml polypropylene test tubes. Experiments were carried out with 260-microliter aliquots of plasma containing a tracer amount of [G-(3)H]paclitaxel with high-specific activity against an equal volume of 0.01 M phosphate buffer (pH 7.4). Drug concentrations were measured by both reversed-phase HPLC and liquid scintillation counting. Using this method, fu has been measured in three patients receiving three consecutive 3-weekly courses of paclitaxel at dose levels of 135, 175, and 225 mg/m(2) and found to range between 0.036 and 0.079. The method was also used to define concentration-time profiles of unbound drug, estimated from the product of the total plasma concentration and fu.     

Changes in lignocaine disposition during long-term infusion in patients with acute ventricular arrhythmias

Lignocaine disposition was studied in 30 patients with acute ventricular arrhythmias. Serum concentrations of lignocaine, its metabolites Monoethylglycine xylidide (MEGX) and glycine xylidide (GX), and alpha 1-acid glycoprotein (AAG) were analyzed during and after a 48-h lignocaine infusion. AAG concentrations tended to rise in patients with acute myocardial infarction (AMI), leading to binding of the drug in plasma. Lignocaine clearance was estimated at various times during the infusion using a Bayesian parameter estimation program and was found to decline over the course of the infusion. There was a significant reduction in clearance based on estimates obtained at the end of the infusion compared with estimates obtained during the first 0-5 h. Clearance was reduced both in patients who had an AMI and those who did not. Multiple linear regression analysis of the clearance data revealed that these changes could be described by a linear function of time and AAG concentration. These findings suggest that other factors in addition to protein binding changes may influence lignocaine disposition during long-term infusion.     

Saliva and serum concentration of lamotrigine in patients with epilepsy

The authors examined the interindividual correlation between saliva and serum concentrations of lamotrigine (LTG) and the relationship between LTG concentration in saliva and the free LTG concentration in serum in 40 patients with epilepsy, aged 16 to 73 years, receiving stable doses of LTG and comedication. Saliva was collected before and after stimulation of salivary flow. The free LTG fraction was determined by equilibrium dialysis and ultrafiltration. Drug analysis was performed by high-performance liquid chromatography. The correlation between LTG daily dose and serum concentration was weak but significant (r = 0.47). There was high correlation between LTG concentration in serum and unstimulated (r = 0.85) or stimulated (r = 0.94) saliva, and between total LTG concentration in serum and the free LTG fraction as determined by ultrafiltration (r = 0.95) and equilibrium dialysis (r = 0.93). Lamotrigine concentration in stimulated saliva was significantly correlated to the free LTG fraction. Protein binding of LTG calculated from concentration in stimulated saliva, as determined by ultrafiltration and equilibrium dialysis, was 51.8% +/- 13.03%, 68.05% +/- 7.59%, and 58.72% +/- 7.68% (mean +/- standard deviation) respectively. The differences between the three methods were significant. The authors conclude that saliva sampling may be a useful alternative to blood tests for monitoring LTG treatment.     

High-throughput determination of the free fraction of drugs strongly bound to plasma proteins

Quantification of protein binding of new chemical entities is an important early screening step during drug discovery and is of fundamental interest for the estimation of safety margins during drug development. In this publication, we describe the development of a new high-throughput assay for the determination of the free drug fraction in plasma (fu). The new technique is an enhancement of the previously published erythrocytes partition method. It is based on the distribution of drugs between plasma water, plasma proteins, and solid-supported lipid membranes (Transil). The execution of protein binding studies by partitioning is dramatically simplified by substituting erythrocytes with commercially available Transil beads, and makes the method particularly suitable for high-throughput studies. Eight Bayer compounds from different compound classes covering a wide range of lipophilicities (log P = 1.9-5.6) and fu values (0.018-35%) were selected for validation of the assay. The results obtained by the new method and by either the erythrocytes partitioning technique or more conventional methods (ultrafiltration and equilibrium dialysis) are identical, confirming that the new method produces valid results even for drugs that are strongly bound to plasma proteins. Precision and accuracy of the data in the cases of very low and high fu values are comparable, indicating that the method is especially suited for highly lipophilic drugs that tend to adsorb to surfaces compared with other methods, like ultrafiltration or equilibrium dialysis, that may produce biased data. The method is also useful for the determination of binding parameters and the pH dependence of fu. In summary, this assay is well suited for high-throughput determination of protein binding during drug discovery and for extended protein binding studies during drug development.