Quaternized colestipol, an improved bile salt adsorbent: in vitro studies

Colestipol.HCl (col-HCl) was quaternized with methyl iodide to form col-CH3l. The in vitro binding capacities of the quaternized and protonated resins in water and in Tris-HCl buffer (0.0015 and 0.0025 M, pH 7.0) at approximately 22 degrees C for sodium glycocholate (NaGC) was determined by reversed-phase HPLC. The binding capacities were found to depend on the adsorption medium. In water, the binding capacity of col-CH3l was 30% greater than that of its protonated form. In Tris-HCl buffer at pH 7.0, the binding capacities of the resins were similar. When the quaternized colestipol was converted to its chloride form, the binding capacity for NaGC in Tris-HCl increased significantly and was 30% greater than that for its protonated analogue. In Cotazym 65B-water, a medium used to test the binding capacity of the resins in the presence of various agents (to try to simulate intestinal conditions), the binding capacity of the quaternized resin was again greater than that of its protonated form. Quaternization thus increases the in vitro binding capacity of colestipol for the glycocholate anion.     

Bile acid salt binding with colesevelam HCl is not affected by suspension in common beverages

It has been previously reported that anions in common beverages may bind to bile acid sequestrants (BAS), reducing their capacity for binding bile acid salts. This study examined the ability of the novel BAS colesevelam hydrochloride (HCl), in vitro, to bind bile acid sodium salts following suspension in common beverages. Equilibrium binding was evaluated under conditions of constant time and varying concentrations of bile acid salts in simulated intestinal fluid (SIF). A stock solution of sodium salts of glycochenodeoxycholic acid (GCDC), taurodeoxycholic acid (TDC), and glycocholic acid (GC), was added to each prepared sample of colesevelam HCl. Bile acid salt binding was calculated by high-performance liquid chromatography (HPLC) analysis. Kinetics experiments were conducted using constant initial bile acid salt concentrations and varying binding times. The affinity, capacity, and kinetics of colesevelam HCl binding for GCDC, TDC, and GC were not significantly altered after suspension in water, carbonated water, Coca-Cola, Sprite, grape juice, orange juice, tomato juice, or Gatorade. The amount of bile acid sodium salt bound as a function of time was unchanged by pretreatment with any beverage tested. The in vitro binding characteristics of colesevelam HCl are unchanged by suspension in common beverages.     

Study of partition of nitrazepam in bile salt micelles and the role of lecithin

The effect of trihydroxy (sodium cholate and sodium glycocholate) and dihydroxy (sodium deoxycholate and sodium glycodeoxycholate) bile salt micelles on the spectrophotometric properties and on the solubility of nitrazepam in aqueous solution, at 25.0 degrees C and at ionic strength 0.1 M in sodium chloride, has been assessed. From the results obtained it was possible to calculate the partition coefficients (Kp) of nitrazepam between aqueous and micellar phases. The partition coefficients of nitrazepam have also been determined in mixed micelles of cholate or deoxycholate with lecithin (egg yolk phosphatidylcholine), which were used as a model of the gastrointestinal tract. Drug partition was found to depend on the bile acid (number of hydroxyl groups and conjugation with glycine), and our data indicate further that addition of lecithin to bile salt micelles decreases the values of the partition coefficients in the mixed micelles at physiological pH.     

Biorelevant dissolution media: aggregation of amphiphiles and solubility of estradiol

Biorelevant dissolution media containing bile salt and lecithin at concentrations appropriate for fed and fasted state are useful when testing oral solid formulations of poorly water-soluble drugs. Dilution of amphiphile solutions affects the aggregation state of the amphiphiles because bile salt is partitioned between the aqueous phase and the aggregates. The aim of the investigation was to study the effect of dilution on the size distribution of aggregates and its effect on the solubilization capacity. Clear buffered solutions of four intestinal amphiphiles (sodium glycocholate, lecithin, monoolein, and oleic acid) and a combination of these were prepared at high bile salt concentration. Micelles in the glycocholate solutions decreased in size when diluted. The addition of insoluble amphiphiles led to bigger micelles with no clear correlation between size of the micelles and amphiphile concentration. Dilution of the two- and four component media caused enlargement of the mixed micelles and formation of vesicles. The solubility of estradiol in the buffer solution was increased with addition of the amphiphiles. A good correlation (R(2) = 0.987) was found between estradiol solubility and mass concentration of the amphiphiles. The results demonstrate that, in the case of estradiol, the concentration of amphiphiles rather than the aggregation state determines the solubilization capacity of the medium.     

Bile salt binding properties of commonly used gastrointestinal drugs: maalox, carafate, and questran

We have validated a method to measure bile salt binding by Maalox (aluminum hydroxide and magnesium hydroxide), Carafate (sucralfate), and Questran (cholestyramine) in vitro. The method used in this study involves a correction for adherent water volume and thus provides a correct measure of bile salt binding. With this approach, we described the binding properties of Maalox, Carafate, and Questran. The bile salt binding capacities of Carafate and Maalox are limited and do not have physiological or pharmacological significance. On the other hand, we found that Questran has substantial bile salt binding capacity. At the recommended dosage, Questran could deplete the total bile salt pool. We also found that Carafate, although not used as an antacid, has buffering capacity (maintaining a pH of solution in the range 4.2-4.8) which might contribute to its effectiveness as an ulcer treatment drug.     

Small Intestinal Absorption of Bropirimine in Rats and Effect of Bile Salt on the Absorption

The intestinal absorption characteristics of a poorly water-soluble drug, bropirimine, were investigated by the in-situ small intestinal loop method using male Sprague-Dawley rats. Bropirimine in solution was well absorbed in the overall small intestine, following first-order kinetics. The rate determining step for the disappearance of bropirimine from the small intestinal loop after dosing in the suspension was the dissolution process from suspension. Bropirimine was solubilized by sodium glycocholate. The disappearance of bropirimine from the small intestinal loop was suppressed by sodium glycocholate contained in the solution, because of the loss of thermodynamic activity of bropirimine after its involvement in the micellar complex, not by the direct effect of bile salt on the permeability of intestinal mucosa. The disappearance of bropirimine was also suppressed by sodium glycocholate contained in the suspension. The suppression by sodium glycocholate seemed to be caused by the greater influence of sodium glycocholate on the thermodynamic activity of bropirimine than on the dissolution from suspension.     

含胆盐脂质体体外稳定性影响因素的研究

以钙黄绿素为小分子水溶性荧光探针,采用薄膜分散法制备了平均粒径为150～200 nm的胆盐脂质体(含甘氨胆酸钠,SGC-Lip)和普通脂质体(含胆固醇,CH-Lip)。通过比较两种脂质体在生理范围内的pH、渗透压、胆盐溶液环境中药物的泄漏率,粒径及多分散系数(PDI)的变化来考察胆盐脂质体的稳定性。结果表明,pH和胆盐浓度是影响脂质体稳定性的主要因素,渗透压对脂质体的稳定性影响较小。SGC-Lip在pH 1.2、2.0及低浓度牛黄胆酸钠(<5 mmol/L)溶液中比CH-Lip更稳定。SGC-Lip在不同溶液中粒径和PDI无显著改变,提示胆盐对脂质膜的作用可能是通过对膜的溶蚀形成孔道,而不是使脂质体完全破裂。     

Equilibrium and Kinetic Factors Influencing Bile Sequestrant Efficacy

In vitro bile salt binding equilibria and kinetic studies were performed with cholestyramine to determine how these factors influence bile sequestrant efficacy in vivo. Chloride ion at physiologic concentrations caused more than a twofold reduction in glycocholate (GCH) binding, compared to binding in the absence of salt, over a range of GCH concentrations and was also observed to displace bound GCH. In addition, chloride ion displaced from cholestyramine as a result of bile salt binding was measured using a chloride selective electrode, and the results show that bile salt binding is due to ion exchange. Comparison of the results of the equilibrium binding experiments to human data shows that the effect of anion binding competition alone cannot account for the lack of efficacy of cholestyramine. Consideration of other effects, such as additional binding competition or poor availability for binding, based on data from the literature, shows that adequate bile salt binding potential exists and that these interferences are not major factors influencing resin efficacy. In kinetic studies, both binding uptake of GCH and displacement of GCH from cholestyramine by chloride ion were relatively rapid, indicating that cholestyramine should equilibrate rapidly with bile salts in the GI tract. Based on these findings, it is suggested that the low efficacy of cholestyramine is a result mainly of its relatively poor ability to prevent bile salt reabsorption in the ileum.     

Receptor-mediated stimulation of taurocholate efflux from the rat hepatocyte and the ex vivo perfused rat liver

The peptide hormone, arginine-vasopressin[( Arg8]vasopressin, AVP), stimulates efflux of the bile salts taurocholate and glycocholate from the rat hepatocyte in suspension via its association with the V1 receptor on the hepatic cell membrane. At a concentration ratio of 5:1 (antagonist to hormone), the V1 vasopressin antagonist, (dCH2)5Tyr(Me)AVP, inhibits the vasopressin induced efflux of taurocholate by approximately 82%, and of glycocholate, by approximately 85%. In contrast, the V2 antagonist (d(CH2)5[D-Ile2,Ala4]AVP, does not interfere with the stimulation of taurocholate and glycocholate efflux by vasopressin. In the isolated perfused rat liver, vasopressin (5 X 10(-10) M) causes an immediate increase of 55 +/- 12% over baseline in [14C]taurocholate secretion and a corresponding increase in bile flow. A more gradual and prolonged increase in [14C]taurocholate secretion, reflecting an increased biliary concentration of [14C]taurocholate, is observed beginning 6 min after vasopressin, reaching a plateau of 23 +/- 12% over baseline by 14 min and returning to baseline by 30 min. The mean rate of 14C secretion during the 30 min following administration of vasopressin (non-steady state) is increased by 14.3 +/- 6.4% over pre-infusion steady-state baseline (P less than 0.05). Prior administration of the V1 receptor antagonist d(CH2)5Tyr(Me)AVP attenuates these effects of vasopressin. The combination of these in vitro and in vivo findings suggest that vasopressin may play a role in regulating bile salt efflux. Furthermore, these studies in the isolated hepatocyte and the intact liver may provide a unique approach for defining biochemical changes associated with bile salt transport from the hepatic cell.     

Examination of the solubilization of drugs by bile salt micelles

The purpose of this review is to provide a critical examination of the reported solubilization of drugs by bile salt micelles. The underlying premise is that with better information regarding the inherent biological complexity, efforts to predict the oral bioavailability of drug will be enhanced. The common means of comparing the reported values was chosen to be the solubilization ratio. This is equal to the moles of drug solubilized per mole of bile salt. The values were segregated according to bile salt type, temperature, ionic strength, and the presence and absence of added lipids. Only segregation by bile salt type was pairwise statistically significant. From the solubilization ratios and the reported values of the aqueous solubility, the logarithms of the mole fraction micelle partition coefficients, log K(m/a), were calculated. The log K(m/w) was found to be correlated with the reported logarithm of the octanol/water partition coefficient. The rank order of slopes of the log K(m/a) as a function of log K(o/w) was cholate approximately taurodeoxycholate > glycocholate approximately taurocholate approximately glycodeoxycholate, with deoxycholate not being statistically different from the other data sets. The slope and intercept for the bile salt mixed micelle systems were 0.600 and 2.44, respectively, which were statistically indistinguishable from glycocholate, taurocholate, and glycodeoxycholate bile salt data. The existence of statistically significant correlations suggests that predicting the solubilization in the intestine may be possible with in vitro measurements if additional information is gathered in the appropriate micellar solutions.     

Characterization of fasted-state human intestinal fluids collected from duodenum and jejunum

The solubility of drugs in the gastrointestinal tract is very challenging to simulate with artificial media due to the high complexity of human intestinal fluid (HIF). In particular, bile salt composition, pH and buffer capacity are very important characteristics of HIF, since they determine the solubility of drugs in-vivo. In this study, we have measured the concentrations of individual bile salts in human intestinal fluids (n=6) collected from two different locations (duodenum and jejunum) in the fasted state. Total bile salt concentrations ranged from 570 to 5,137 microM in the duodenum and from 829 to 5,470 microM in the jejunum. The following rank order of relative bile salt concentration in duodenum was observed: taurocholic acid > glycocholate >or= glycochenodeoxycholate > glycodeoxycholate > taurochenodeoxycholate > taurodeoxycholate. Cholic acid, tauroursodeoxycholate, chenodeoxycholic acid, and deoxycholic acid represented less than 1% of bile salts present in the samples. Ursodeoxycholate could not be detected in HIF. No statistically significant difference between bile salt composition of duodenal and jejunal aspirates was observed. The buffer capacity of HIF was compared with other media commonly used for solubility/dissolution determinations, indicating a relatively low buffer capacity of HIF (4-13 mmol L(-1)/pH). This low buffer capacity was reflected in the change in pH (between 4 and 9.5) that occurred in HIF after addition of model compounds covering a broad pK(a) range. Interindividual variability in pH, buffer capacity and bile salt contents of HIF will contribute to differences in the rate and extent of absorption of compounds for which dissolution/solubility is the rate limiting step. The variability observed warrants further research to explore the impact of intraluminal conditions on drug solubility.     

Light-scattering studies on bile acid salts I: Pattern of self-association of sodium cholate, sodium glycocholate, and sodium taurocholate in aqueous electrolyte solutions

The pattern of association of the trihydroxy bile salts in aqueous electrolyte solutions was investigated utilizing the light-scattering technique. The turbidity of the bile salts sodium cholate, sodium taurocholate, and sodium glycocholate was determined over the concentration range of 0-25 mg/ml at 25 degrees. For sodium cholate, the concentration of the supporting electrolyte was varied from 0.15 to 0.5 M. For all bile salts in 0.15 M electrolyte, the turbidity was determined in sodium fluoride, sodium chloride, sodium bromide, and sodium iodide. Comparison of the light-scattering data with amonomer-micellar model showed that qualitative agreement was obtained; however, quantitative agreement could not be achieved. Further examination of the data showed that the light-scattering results were in good agreement with a model that includes dimers, trimers, and a higher aggregate containing approximately eight monomeric units.     

Conjunctival Penetration of Insulin and Peptide Drugs in the Albino Rabbit

An in vitro model was used to evaluate the conjunctival penetration of three peptides, [D-ala²]metenkephalinamide (YAGFM, MW 647), substance P (MW 1348), and insulin (MW 5778), in comparison with two nonpeptides, atenolol (MW 266) and timolol (MW 433). All three peptides were hydrolyzed to varying extents during penetration across the conjunctiva. The permeability coefficient for intact YAGFM and insulin was 4.5 ± 0.3 and 4.6 ± 0.7 µm sec^–1, respectively. These values were about two to five times lower than those for atenolol and timolol. No permeability coefficient could be calculated for substance P, since its transconjunctival flux never reached steady state. The conjunctival penetration of YAGFM and insulin was improved by about two and three times, respectively, with the addition of 1% Na glycocholate. Increasing the Na glycocholate concentration was more effective than changing the type of bile salt in improving the conjunctival penetration of insulin. The maximum factor of improvement was 12, as the Na glycocholate concentration was raised to 4%. The way in which Na deoxycholate, glycocholate, and taurocholate affected the conjunctival penetration of atenolol, timolol, and insulin suggests that these three bile salts improved mainly the transcellular penetration of the compounds studied.     

Nasal Membrane and Intracellular Protein and Enzyme Release by Bile Salts and Bile Salt-Fatty Acid Mixed Micelles: Correlation with Facilitated Drug Transport

The effects of four bile salts, one fusidate derivative, and one mixed micellar formulation of bile salt-fatty acid combination on the nasal mucosal protein and enzyme release have been investigated in rats using an in situ nasal perfusion technique. Deoxycholate (NaDC) was found to possess the maximum protein solubilizing activity, followed by taurodihydrofusidate (STDHF), cholate, glycocholate (NaGC), and taurocholate (NaTC) in a descending order. The difference in protein solubilization of NaDC and NaGC was further characterized by the release of 5-nucleotidase (5-ND), a membrane-bound enzyme, and lactate dehydrogenase (LDH), an intra-cellular enzyme, in the perfusate. While both NaDC and NaGC caused comparable 5-ND release from nasal membrane, intracellular LDH release was significantly higher with NaDC. The greater protein and LDH solubilizing effects of NaDC corresponded well with its faster rate of disappearance from the nasal perfusate. Therefore, the dihydroxy bile salt NaDC tends to cause intracellular damage and cell lysis, whereas the trihydroxy bile salt NaGC appears to produce primarily mucosal membrane perturbations. Linoleic acid in the form of soluble mixed micelles with glycocholate caused a further increase in nasal protein release. However, the rate and extent of nasal membrane protein release by the mixed micelles composed of 15 mM glycocholate and 5 mM linoleic acid were significantly lower than those caused by either deoxyholate or STDHF at the same concentrations. Nasal absorption of acyclovir, a non-absorbable hydrophilic model antiviral agent, was found to be enhanced in the presence of conjugated trihydroxy bile salts and bile salt-fatty acid mixed micelles. A nonlinear correlation exists between first-order nasal absorption rate constant and nasal protein release rate.     

Effect of chenodeoxycholate feeding upon the biliary output of plasma membrane enzymes in the rat

In model experiments using human erythrocytes, glycochenodeoxycholate caused extensive membrane damage (as judged by release of membrane phospholipid and acetylcholinesterase and by cell lysis) at approximately 10-fold lower concentrations than glycocholate. Chenodeoxycholate feeding had no effect upon the total protein, bile salt or phospholipid concentration of rat bile, although evidence is presented to suggest an expansion of the bile salt pool occurred. Rats fed chenodeoxycholate showed a dose-dependent enrichment of this bile acid in bile; this occurred mainly at the expense of cholate. Chenodeoxycholate feeding resulted in an increased biliary output of the plasma membrane enzymes alkaline phosphatase and 5'-nucleotidase; the hepatic activities of these enzymes were also increased. In contrast, the biliary output and hepatic activities of two other plasma membrane enzymes, alkaline phosphodiesterase I and L-leucine-beta-naphthylamidase, were unaffected by chenodeoxycholate feeding. A greater proportion of all four plasma membrane enzymes studied existed in bile of chenodeoxycholate-fed rats in a "soluble" form (as judged by their remaining in the supernatant on centrifugation of bile). These results are discussed in relation to the origin of plasma membrane enzymes in bile and to the potential toxicity of chenodeoxycholate and its conjugates to the membranes of the hepatobiliary system.     

High and low affinity binding of [3H]cholate to rat liver plasma membranes

The transport of bile acids across sinusoidal and canalicular membranes of hepatocytes is characterized as carrier mediated. Such a carrier should specifically bind bile acids at physiological concentrations. We examined the binding of [3H]cholate to rat liver plasma membranes using a microcentrifugation technique and detected high (KD = 1.23 +/- 0.44 microM, Bmax = 21.8 +/- 3.3 pmol/mg protein) and low (KD = 1.97 +/- 1.33 mM, Bmax = 41.5 +/- 25.3 nmol/mg protein) affinity binding sites. Maximal binding was achieved within 15-45 sec and was stable for 2 min at 37 degrees. Binding to the high affinity site was reversible, was not Na+ dependent or attributable to vesicular uptake, and exhibited a broad pH optimum. Binding to this site was negligible or not detected in liver mitochondrial and microsomal fractions, was saturable, and was inhibited by other bile acids. The IC50 values for bile acids as inhibitors of [3H]cholate binding at the high affinity site were: taurocholate, 1.9 nM; glycodeoxycholate, 3.1 nM; chenodeoxycholate, 5.6 nM; taurochenodeoxycholate, 7.3 nM; glycochenodeoxycholate, 11 nM; lithocholate, 13 nM; taurodeoxycholate, 20 nM; glycocholate, 3.6 microM; and deoxycholate, 5.6 microM. [3H]Cholate specific binding was inhibited by 10(-5) M bromosulfophthalein, bilirubin and indocyanin green. These data support the hypothesis that the high affinity binding site represents a carrier which is shared by bile acids and nonbile acid organic anions.     

Absorption of recombinant methionyl-human growth hormone (Met-hGH) from rat nasal mucosa

The absorption of recombinant methionyl human growth hormone (Met-hGH) from the nasal mucosa into the systemic circulation was studied in anesthetized rats. Met-hGH was administered intranasally (i.n.), intramuscularly (i.m.) and intravenously (i.v.) to determine the relative and absolute bioavailability of an intranasal Met-hGH formulation. In the absence of detergent enhancers, the absolute bioavailability of meth hGH was <1%. Hypotonicity enhanced absorption slightly. The absolute bioavailability of Met-hGH increased markedly in the presence of the non-ionic surfactant, polyoxyethylene 9-lauryl ether (laureth-9). The histological changes in the nasal mucosa of rats treated with 1% laureth-9 were severe, however, and included complete removal of the nasal epithelium in places. The bile salt sodium glycocholate was also evaluated for its permeation enhancing abilities. At 0.5% glycocholate there were few noticeable histological changes relative to controls and the absolute biovailability of Met-hGH was approximately 7–8%. While absorption of Met-hGH from the nasal epithelium is demonstrated, the effects of permeation enhancing detergents on the delicate nasal mucosa must be better understood before the intranasal route of administration may be considered suitable for delivering Met-hGH to the systemic circulation.     

Biotransformation of a GABAA receptor partial agonist in sprague-dawley rats and cynomolgus monkeys: identification of two unique N-carbamoyl metabolites.

The absorption, metabolism, and excretion of N-[3-fluoro-4-[2-(propylamino)ethoxy]phenyl]-4,5,6,7-tetrahydro-4-oxo-1H-indole-3-carboxamide monomethanesulfonate (1), a GABAA receptor partial agonist potentially useful in treating generalized anxiety disorder, have been evaluated in both Sprague-Dawley rats and cynomolgus monkeys using [14C]1. In both species, mass balance was achieved within 48 h postdose, with the majority of drug-related material excreted within the feces; the clearance of 1 in each species had both metabolic and renal components. In addition to the metabolites produced by aliphatic hydroxylation and/or N-dealkylation of 1, two unique metabolites were detected: a putative carbamic acid (M7) in rat plasma and monkey bile, and an N-carbamoyl glucuronide (M8) in both rat and monkey bile. Metabolite M8 was structurally deciphered by liquid chromatographytandem mass spectrometry and NMR, and was readily generated in vitro upon incubation of [14C]1 with rat liver microsomes fortified with uridine 5'-diphosphoglucuronic acid trisodium salt and alamethicin under a CO2 atmosphere. Treatment of M8 with beta-glucuronidase afforded 1 directly. The presence of M8 in bile and its notable absence from other matrices suggests the enterohepatic cycling of 1 via M8. Although the structure of M7 was not elucidated unequivocally due to its inability to be formed in vitro and its minimal absolute quantities in limited biological matrices, data herein clearly support its structural rationalization. Furthermore, since M7 is the precursor of M8, detection of M8 is indirect evidence of its existence. It is proposed that M7 arises from an equilibrium between 1 and dissolved CO2-equivalents both in vivo and in vitro, similar to carbamino bonds observed in hemoglobin and certain amino acids, respectively.     

Advances in the design of fasted state simulating intestinal fluids: FaSSIF-V3

Biorelevant media are commonly used to simulate the physiological composition of human intestinal fluids (HIF) in in vitro solubility and dissolution investigations. In comparison with the surfactant solutions or blank buffers, these media are able to better reflect the physiological solubility and dissolution behavior of poorly soluble active pharmaceutical ingredients (APIs). The aim of this investigation was to review the composition of FaSSIF and FaSSIF-V2 according to recently summarized data about the physiological composition of fasted state human intestinal fluid and propose an updated version, FaSSIF-V3. Furthermore the surface tension was considered as a possible surrogate parameter to gauge the physiological correctness of new versions of biorelevant media.Various prototypes of FaSSIF-V3 were prepared with each of the following five bile salts: taurocholate (TC), glycocholate (GC), tauroursodeoxycholate (TUDC), taurochenodeoxycholate (TCDC) and glycochenodeoxycholate (GCDC) as well as replacing lecithin with its hydrolysis products, lysolecithin and sodium oleate. Two additional media consisting of a mixture of glycocholate (GC) and taurocholate (TG), with or without 0.2 mM cholesterol, were also investigated.Solubilities of ten model compounds in various prototypes of FaSSIF-V3 were measured using HPLC-UV and compared to the solubilities in the existing biorelevant media (FaSSIF and FaSSIF-V2), fasted HIF, blank buffer and a 0.5% sodium dodecyl sulfate (SDS) solution. Additionally, the influence on the surface tension properties of various combinations of bile salts, phospholipids and their hydrolysis products and cholesterol in these media was investigated and an attempt was made to calculate the CMC of the various generations of FaSSIF.The results demonstrated that the amount and the type of phospholipids as well as the type of bile salt had a significant influence on the solubility and surface tension in the various FaSSIF-V3 prototypes and existing biorelevant media. In contrast to results with biorelevant media, it was demonstrated that blank buffers generally underestimate and SDS solutions highly overestimate the physiological relevant solubilities of all investigated APIs.The prototype containing FaSSIF-V3-GC/TC_Chol was able to better reflect the solubilities of the most investigated APIs in fasted HIF than the existing media, and it also matched the physiological surface tension reported for the fasted human gut, and was designated FaSSIF-V3.     

In Vitro Adsorption of Bile Salts by Colestipol Hydrochloride

The acid–base titration of colestipol hydrochloride exhibits no sharp inflection points, indicating a weakly basic anion-exchange copolymer. The swelling of colestipol hydrochloride in water and the adsorption of cholate anion are inversely related to pH and are, therefore, related to the ionization state of the copolymer. The Langmuir adsorption parameters at pH 7.5 and 37°C are similar for cholate, glycocholate, and taurocholate anions. Adsorption capacity was not related to particle size and exceeded the adsorptive capacity of the external surface by three orders of magnitude. Therefore, it is believed that the swelling of colestipol hydrochloride makes extensive internal surface area available for adsorption of bile salts. The rate of adsorption depends on the concentration of sodium cholate to which the colestipol hydrochloride is exposed. Adsorption was complete within 5 min when the concentration was below the adsorptive capacity. In contrast, adsorption at levels of sodium cholate at or above the adsorptive capacity was not complete within a 3-hr test period.