Drug Binding and Solubility in Milk

The binding and solubility of nitrofurantoin, piroxicam, indomethacin, prednisolone, diazepam, dicumarol, and griseofulvin in milk were determined at 15, 25, and 37°C in bovine milk samples with fat contents of 0.75 and 3.50%. Drug binding to milk components was independent of drug concentration over the drug concentration studied, and the fat content of milk strongly affected binding values of most of the listed drugs. Further, drug binding increased with decreasing temperatures for most of the drugs examined. The solubility of all drugs is greatly enhanced in milk compared to their aqueous solubility (pH 6.5 phosphate buffer). The high solubility cannot be accounted for solely on the basis of drug binding to milk components. An attempt is made to correlate the binding and solubility data with physicochemical properties of the drugs (logP, pK _a, aqueous solubility). The potential significance of these findings is discussed with regard to preparation and in vivo delivery of drugs from drug–milk formulations.     

Preparation and in vivo evaluation of piroxicam-loaded gelatin microcapsule by spray drying technique

To develop a piroxicam-loaded gelatin microcapsule with enhanced bioavailability, a gelatin microcapsule encapsulated ethanol and piroxicam has been formulated by using gelatin as a water-soluble polymer shell. The aqueous solubility and bioavailability of piroxicam in piroxicam-loaded microcapsule in rats were then evaluated compared to piroxicam powder. The piroxicam-loaded gelatin microcapsule spherical in shape with smooth surface showed the geometric mean diameter of about 19 microm. It had the piroxicam solubility of about 1.87 mg/ml and the amount of ethanol of about 4.37 microg/mg. Furthermore, it gave significantly higher total plasma concentrations, Cmax and area under the blood concentration-time curve (AUC) of piroxicam in rats than did piroxicam powder, indicating that the drug from gelatin microcapsule could be more orally absorbed in rats. In particular, the AUC of piroxicam in gelatin microcapsule was significantly about 2 fold increased compared to piroxicam powder. This enhanced oral relative bioavailability of piroxicam in gelatin microcapsule was contributed by the marked increase in the absorption rate of piroxicam due to the improved solubility of piroxicam. Thus, the piroxicam-loaded gelatin microcapsule developed using spray-drying technique with gelatin, sodium lauryl sulfate and ethanol would be useful to deliver piroxicam in a pattern that allows fast absorption in the initial phase, leading to better absorption.     

Combined effect of pH and polysorbates with cyclodextrins on solubilization of naringenin

pH control and inclusion complex formation are commonly used as solubilization techniques in formulating ionizable drugs. Naringenin is a weakly acid compound with a low water solubility. The role of both ionized and unionized species of naringenin in solution by complexation with beta-cyclodextrin, 2-hydroxypropyl-beta-cyclodextrin and methyl-beta-cyclodextrin was investigated. This combined use of ionization and complexation increases not only the solubility of the unionized naringenin, but also that of the ionized one. This study puts on evidence the role of pH, pKa and complexation constants in increasing drug total aqueous solubility, determined by the single components in solution, as ionized and unionized naringenin both in free and complexed forms. Moreover, the presence of non-ionic surfactants in the media of complexation gives a positive contribution to the improvement of the solubility of naringenin, alone or in combination with beta-cyclodextrin.     

Solubilization of ionized and un-ionized flavopiridol by ethanol and polysorbate 20

Because the ionized species is more polar than its un-ionized counterpart, it is often assumed that the ionized species of the drug does not make a meaningful contribution to solubilization by either cosolvents or surfactants. This report extends previous studies on solubilization of the ionic species by a combination of pH control and complexation to pH control and micellization and to pH control and cosolvency. The total aqueous solubility is expressed as the addition of the concentration of all contributing species: free un-ionized drug [Du], free ionized drug [Di], un-ionized drug micelle [DuM], and ionized drug micelle [DiM] for surfactant, and free un-ionized drug [Dcu] and free ionized drug [Dci] for cosolvent. The equations indicate that under certain conditions the ionized species can be more important in determining the drug total solubility than the un-ionized species. Flavopiridol, a weak base, is used to test these newly generated equations. As expected, the micellar partition coefficient and solubilization power for ionized flavopiridol are both less than those of the un-ionized species. However, at acidic pH, the solubilities of the ionized drug in surfactant micelles [DiM] and in cosolvent-water [Dci] are both much greater than that of the un-ionized drug. This difference is because the solubilization of the ionized drug is proportional to its aqueous solubility, and its solubility [Di] can be as much as 24-fold greater than that of the free un-ionized species [Du].     

Effect of pH and complexation on transdermal permeation of gliquidone

Gliquidone, a second generation sulfonylurea has been investigated for transdermal delivery. The poor aqueous solubility of the drug prompted the use of hydroxypropyl-beta-cyclodextrin (HP-beta-CD), a cyclic oligosaccharide, which is known to facilitate transdermal permeation of many drugs by enhancing the solubility and thus improving the diffusible species of the drug molecules at the skin-vehicle interface. In order to optimize the transdermal delivery of gliquidone, the effect of pH along with complexation on the solubility and permeation has been investigated. The solubility profiles of the drug, on increasing the concentration of HP-beta-CD were of Higuchi's AL type at the three pH values evaluated. However, the solubilization slope of the drug at pH 7.0 was 22 times that at pH 3.0 as a result of greater intrinsic solubility of the ionized form of the drug at pH 7.0. Transdermal flux of gliquidone at pH 7.0 was significantly greater than the flux at pH 3.0 in the presence of 15% w/v HP-beta-CD, attributable to the better solubility of the drug at pH 7.0 in the presence of HP-beta-CD. The effect of increasing concentrations of HP-beta-CD investigated at variable drug loading in the donor phase at pH 7.4 endorsed the earlier observations from studies on other drugs, that the drug has to be present at saturation in HP-beta-CD aqueous vehicle to achieve an optimized flux. While at saturation, the steady state flux of gliquidone from the aqueous HP-beta-CD (25% w/v) vehicle was enhanced 31 times compared to pure drug suspension at pH 7.4, unsaturation in the donor phase resulted in the decreased flux of gliquidone. It was concluded from the present study that enhanced transdermal flux of gliquidone can be achieved by adjusting the pH and the concentration of HP-beta-CD to achieve a better solubility of the drug.     

Effect of pH on the solubility and release of furosemide from polyamidoamine (PAMAM) dendrimer complexes

The complexation of the practically insoluble drug furosemide (acidic pK(a) 3.22) with lower generation PAMAM dendrimers showed a significant release dependence on the ionization state of the drug. UV and FTIR studies suggested that the drug was localized in the interior of the dendrimer. The dendrimer amine, amide and ester groups, demonstrated pH-dependent ionization as did the drug carboxylic acid group and it was proven that the most efficient drug complexation was achieved in slightly acidic conditions (pH 4.0-6.0). At this pH, amide groups in the dendrimer cavities were at least partially ionized to expose a positive charge whilst the furosemide carboxylic acid ionized to great extent (pH>pK(a)) resulting in electrostatic complexation. Conversely, higher release rates were observed in acidic conditions (pH 1.2) where furosemide was virtually unionized, emphasizing the importance of the drug ionization state in the determination of drug release. Despite the complex interactions between the dendrimer and drug and its effects on release kinetics, the dendrimers resulted in higher solubility of the drug and contributed significantly to the array of available techniques to increase the solubility of poorly water-soluble drugs that are very abundant in industry today. Complexation with low generation PAMAM dendrimers (相似文献   

Examination of self-crosslinked gelatin as a hydrogel for controlled release.

A gelatin matrix crosslinked by extensive dehydration was examined for use in controlled drug delivery in this preliminary investigation. Crosslinking is necessary to prevent gelatin dissolution and immediate drug release at body temperature. Treatment at 105 degrees C and reduced pressure induced crosslinking in discs prepared from Type B gelatin. Crosslinking was evaluated by determining changes in gelatin solubility at 37 degrees C in a USP paddle dissolution apparatus. The crosslinking treatment was reproducible and resulted in 90% of the original gelatin mass remaining after 12 h in water and in phosphate buffer solutions of pH 3 and 6.4. The treated gelatin discs remained intact for greater than 24 h at pH 6.4. Chlorpromazine.HCl (CPZ) was incorporated as a model drug by soaking the treated gelatin discs in an aqueous solution of the drug. Release of CPZ at 37 degrees C in the dissolution apparatus was fitted to an empirical equation. A coefficient of this equation was used as the initial release rate for comparison between different release profiles. The roles of drug solubility, matrix swelling and erosion, and potential drug-matrix interactions were examined by conducting release studies at pH values of 3, 4, 6.4, and 7.4. The insoluble, un-ionized form of the drug had the slowest release rate. The soluble, ionized form under conditions of maximum swelling and a possible drug-matrix repulsive interaction had the fastest release rate. General electrostatic drug-matrix interactions were noted which could influence the drug release rate depending on conditions of the study. The times for 50% release of CPZ ranged from 1.8 to 11.3 h.     

Effect of pH on skin permeation enhancement of acidic drugs by l-menthol-ethanol system

The effect of pH on the skin permeation enhancement of three acidic drugs by the l-menthol-ethanol system was investigated. The total flux of acidic drugs from the system remarkably varied over the pH range 3.0-8.0, and the permeation enhancement factor depended on the system pH and drug. A skin permeation model, which consists of two permeant (unionized and ionized) species, two system (oily and aqueous) phases, and two permeation (lipid and pore) pathways, was developed. The assumptions were made that only the unionized species can distribute to the oily phase and transport via the lipid pathway. The model explained the relationship between the concentration of drug in the aqueous phase and system pH. The skin permeability data were also described by the model and permeability coefficients corresponding to the physicochemical properties of permeant were calculated for the lipid and pore pathways. The model simulation showed that the permeation of acidic drugs occurred from the aqueous phase and the oily phase acted as a reservoir. Whether the total flux increased with increase of pH was dependent on the lipophilicity of drug. These results suggest that the pH of l-menthol-ethanol system should be given attention to elicit the maximum permeation enhancement.     

Effect of temperature and fat content on the solubility of hydrochlorothiazide and chlorothiazide in milk

The solubility of hydrochlorothiazide and chlorothiazide in milk has been studied. Experiments were carried out at 5, 15, 25, and 37 degrees C on a buffer solution of pH 6.5, a 2.6% solution of casein, bovine skim milk samples, and bovine milk samples with fat contents of 0.75, 1.70, and 3.50%. The "total" solubility of both drugs in the media studied was higher than the buffer solubility. The highest "total" solubility for both drugs was observed in skim milk. Based on binding data of thiazides to milk, the "total" solubility was split into "free" and "bound" solubility. The increases of solubility noted cannot be explained on the basis of drug-milk binding data. The enhancement of solubility was attributed to the increase of intrinsic solubility of drugs in milk. Results of the thermodynamic analysis of solubility data showed that a different solubilization process of hydrochlorothiazide may be responsible for the high solubility values found in skim milk for this drug. In contrast, the thermodynamic parameters of chlorothiazide in all types of milk are similar, indicating a common solubilization mechanism. The biopharmaceutical significance of the findings is discussed in light of the freeze-dried drug-milk formulations and coadministration of drugs with milk in general.     

羟丙基-β-环糊精与介质pH值对前列腺素E_1溶解度的综合影响（英文）

目的研究羟丙基-β-环糊精（HP-β-CD）与介质pH值对前列腺素E1（PGE1）溶解度的综合影响并进一步推导出该药物溶解度的理论方程。方法首先测定药物在不同pH值水中的溶解度;然后分别测定在酸性及中性系列浓度的HP-β-CD溶液中,药物的溶解度;最后推导出以HP-β-CD与介质pH值为变量的药物溶解度方程并对其合理性进行验证。结果溶解度测定结果表明,提高介质的pH值或以HP-β-CD为增溶剂,均可增加PGE1的溶解度。分子型药物或离子型药物与HP-β-CD测得的相溶解度图均为典型的AL型,提示药物结构上的五元碳环部分已嵌入HP-β-CD的疏水性孔穴中,从而形成1：1摩尔比包合物。结论以HP-β-CD作为增溶剂,同时提高介质的pH值,可对PGE1的溶解度产生协同增加效应。本研究中导出的PGE1溶解度方程,可有效表征HP-β-CD与介质pH值二者对该药物溶解度的综合影响。     

Estimation of the Relative Contribution of the Transcellular and Paracellular Pathway to the Transport of Passively Absorbed Drugs in the Caco-2 Cell Culture Model

Purpose. The objective of this investigation was to determine, using the Caco-2 cell culture model, the extent to which the paracellular and transcellular routes contributed to the transport of passively absorbed drugs. An effort was also made to determine the controlling factors in this process. Methods. We selected a heterologous series of drugs with varying physicochemical parameters for the investigation. Effective permeability coefficients of the model drugs (naproxen, phenytoin, salicylic acid, chlorothiazide, furosemide, propranolol, diltiazem, ephedrine, and cimetidine), at pH 7.2 and pH 5.4, were estimated using confluent monolayers of Caco-2 cells. The biophysical model approach, based on molecular size restricted diffusion within an electrostatic field of force, used by Adson et al. (1 ,2), was employed to estimate the permeability coefficients of the ionized and unionized forms of the drugs for the paracellular and transcellular route. Results and Conclusions. The permeability coefficients of the acidic drugs was greater at pH 5.4, whereas that of the basic drugs was greater at pH 7.2 and the transcellular pathway was the favored pathway for most drugs, probably due to its larger accessible surface area. The paracellular permeability of the drugs was size and charge dependent. The permeability of the drugs through the tight junctions decreased with increasing molecular size. Further, the pathway also appeared to be cation-selective, with the positively charged cations of weak bases permeating the aqueous pores of the paracellular pathway at a faster rate than the negatively charged anions of weak acids. Thus, the extent to which the paracellular and transcellular routes are utilized in drug transport is influenced by the fraction of ionized and unionized species (which in turn depends upon the pKa of the drug and the pH of the solution), the intrinsic partition coefficient of the drug, the size of the molecule and its charge.     

The solubility of drugs in molten suppository bases

Solubility of 18 drugs used in rectal therapy in molten suppository base, (Massa suppositoriorum 15, Pharmacopeia of the G.D.R. Rosupol U, 37 degrees C) is determined. Separation of drug-saturated base from drug cristals is carried out in an air-heated centrifuge followed by a partition step between petroleum ether and an aqueous medium and photometrical determination of drug concentration. The procedure leads to results with relative standard deviation of 2% (medium value of 18 drugs). The investigation gave solubility values in the range between 0.002% (theobromine) and 26% (lidocaine), whereas benzoate, phenobarbital sodium and procaine hydrochloride are completely insoluble. Sodium salicylate has an unexpected high solubility (0.48%). The solubility is temperature depended and thus the solubility enthalpy can be determined. Relations between structure and solubility are discussed for pyrazolin-5-ones and purines. A correlation between solubilities in the base and in aqueous buffer (phosphate, pH 7.4) does not exist in the series studied.     

Solubility and stability of curcumin in solutions containing alginate and other viscosity modifying macromolecules. Studies of curcumin and curcuminoids. XXX

The solubility, chemical- and photochemical stability of curcumin in aqueous solutions containing alginate, gelatin or other viscosity modifying macromolecules have been investigated in order to obtain an alternative to the use of surfactants or cyclodextrins. The solubility of curcumin in aqueous solution at pH 5 increased by a factor > or = 10(4) in the presence of 0.5% (w/v) alginate (various qualities) or gelatin compared to plain buffer, while propylene glycol alginate ester, cesapectin and sodium carboxymethyl cellulose did not have a similar solubilizing effect. The solubilization was slightly influenced by pH, ionic strength and type and concentration of buffer salts. The macromolecules do, however, not stabilize towards hydrolytic- or photolytic degradation of curcumin.     

Solubilization and preformulation of carbendazim

The solubilization of carbendazim by pH in combination with cosolvents, surfactants or complexants was investigated. At pH 7 the total drug solubility is 6.11 +/- 0.45 microg/ml which increases by 1-7 fold with cosolvent, surfactant or complexant. However, at pH 2 the solubility increases by 250 times. Cosolvents have a negligible effect (50% increase) on the total drug solubility at pH 2 because of the high polarity of the cationic drug. Also pH combined with nonionic surfactants does not improve solubility, as relatively less polar micelles are not able to accommodate the cationic drug. Interestingly, the total drug solubility increases by combining pH 2 with complexants, as they can form a complex with the isolated aromatic ring of both the unionized and the ionized drug. The proposed oral formulation of 1 mg/ml carbendazim at pH 2 does not precipitate in the presence of Seven Up or water. But it does precipitate with pH 7 buffer when diluted 1:10 but not 1:100 or 1:250.     

pH值对吡罗昔康理化性质及其经皮渗透性能的影响

目的:研究pH值对吡罗昔康理化性质及经皮渗透性能的影响,为其经皮给药制剂的研究提供实验依据。方法:用HPLC法测定药物在水、不同pH缓冲液(PBS)中的溶解度;采用双波长分光光度法测定药物的解离常数(pKa);摇瓶法测定药物的表观油水分配系数(logP);利用透皮扩散池以稳态渗透速率常数(Js)和通透系数(Ps)为评价指标研究药物的透皮效果。结果:吡罗昔康的pKa为6.33。32℃时,吡罗昔康在pH 7.4的缓冲液中logP为0.17,且溶解度和Js均达到最大,分别为(420.445)μg.mL-1和(64.612±0.011)μg.cm-2.h-1;Ps为(0.154±0.014)cm.h-1。结论:调节药物pH值,使药物维持较高的溶解度和分子型药物比例,可望获得理想的皮肤通透性。     

Factors influencing the fabrication of albumin-bound drug nanoparticles (ABDns): part I. Albumin-bound betulinic acid nanoparticles (ABBns)

Though there are many albumin-based drug delivery systems (ABDDS) in the market, it is not known whether ABDDS can be applied across all chemical classes. In this study, we applied ABDDS to a poorly water-soluble drug betulinic acid (BA) to improve its aqueous solubility. Monomeric albumin-bound BA (ABBns) nanoparticles can be fabricated in the range of 10–20?nm. BA self-assembled with HSA at 0.1:1 to 2:1 molar ratio within 0.5?h in phosphate buffer pH 7.4 and 8.4. Approximately, 85–90% BA could be loaded onto HSA in the presence of Tween 20 (T20) and sodium cholate (NaC). The release of BA from ABBns was linear over 5 days. In conclusion, for poorly water-soluble acidic drugs, a suitable solubiliser can release the drug from HSA binding site, depending on the aggregation number and affinity of the solubiliser for the HSA binding site.     

Optimized transdermal delivery of ketoprofen using pH and hydroxypropyl-beta-cyclodextrin as co-enhancers.

The role of pH and pK(a) of ionizable drugs in transdermal delivery has been well documented by the pH partition hypothesis. Similarly the role of pH in complexation has also been addressed by many studies. Reports contrary to the well believed theory that both molecular encapsulation by hydroxypropyl-beta-cyclodextrin (HP-beta-CD) and transdermal delivery are considered a phenomenon of unionized drug species prompted investigation into the combined effect of pH and HP-beta-CD on transdermal delivery of ketoprofen. In order to optimize the delivery of ketoprofen, solubility studies and permeation studies were conducted in vitro at pH 3.0, 4.5 and 6.0 at various concentrations of cyclodextrin. The stability constants for unionized and ionized drugs were calculated. The solubility of the ionized complex of the drug was 2.5 fold greater than the unionized complex. The flux increased linearly with increasing HP-beta-CD concentration at all the pH values. However, the increase was significant at pH 6.0 where the drug is predominantly in the ionized state. The flux of the ionized drug at 10% w/v HP-beta-CD concentration was enhanced to an order of approximately eight times compared to the intrinsic permeability of the unionized drug. The study shows that at higher pH, HP-beta-CD can be utilized to achieve greater transdermal flux of ketoprofen.     

Solubility Behavior of Narcotic Analgesics in Aqueous Media: Solubilities and Dissociation Constants of Morphine,Fentanyl, and Sufentanil

The pH dependence of the aqueous solubility of morphine, fentanyl, and sufentanil was investigated at 35°C. Dissociation constants and corresponding pK _a values of the drugs were obtained from measured free-base solubilities (determined at high pH's) and the concentrations of saturated solutions at intermediate pH's. Morphine, fentanyl, and sufentanil exhibited pK _a values of 8.08, 8.99, and 8.51, respectively. Over the pH range of 5 to 12.5 the apparent solubilities are determined by the intrinsic solubility of the free base plus the concentration of ionized drug necessary to satisfy the dissociation equilibrium at a given pH. Consequently, the drug concentrations of saturated aqueous solutions fall off precipitously as the pH is raised and ionization is suppressed. Further, at low pH's the aqueous solubility of morphine increased in a linear fashion with increases in the molar strength of citric acid which was added to acidify the medium, suggesting the formation of a soluble morphine–citrate complex.     

Nitrofurantoin solubility in aqueous urea and creatinine solutions.

Experiments were carried out to determine the effect of urea and creatinine on the solubility of nitrofurantoin in water at different temperature and pH conditions. The addition of urea to aqueous media increased nitrofurantoin solubility up to a maximum concentration level and then decreased solubility at higher urea concentrations. The amount of urea needed to bring about maximum nitrofurantoin solubility was dependent on temperature and ranged between 1.75 and 2.50%. Spectral studies suggest a possible interaction between urea and nitrofurantoin molecules. Nitrofurantoin solubility increased with an increasing creatinine concentration ranging from 0.05 to 1.6%. Spectral studies indicate a strong interaction between creatinine and nitrofurantoin molecules in solution. The combined effect of urea and creatinine of the solubility of nitrofurantoin could account for the absence of crystalluria with this drug, even though unusually high concentrations in urine have been reported.     

Influence of methacrylic and acrylic acid polymers on the release performance of weakly basic drugs from sustained release hydrophilic matrices

Weakly basic drugs and their salts exhibit a drop in aqueous solubility at high pH conditions, which can result in low and incomplete release of these drugs from sustained release formulations. The objective of this study is to modulate matrix microenvironmental pH by incorporation of acidic polymers and thus enhance the local solubility and release of basic drugs in high pH environment. Two weakly basic drugs, papaverine hydrochloride and verapamil hydrochloride with widely different pKa and aqueous solubilities at the pH of interest (6.8), were investigated for their release from hydrophilic matrices and the effect of a methacrylic (Eudragit L100-55) and an acrylic acid polymer (Carbopol 71G), were studied. For papaverine HCl, release increased with an increase in the levels of the acidic polymer used. Direct measurement of matrix pH using microelectrodes illustrated that the mechanism of release enhancement was based on modulation of microenvironmental pH. For verapamil HCl, incorporation of L100-55 resulted in release retardation due to an interaction between the anionic polymer and the cationic drug and the extent of retardation increased with an increase in the polymer level. The interaction product was characterized by NIR, FT-IR, and MTDSC techniques. Verapamil HCl release from Carbopol 71G based matrix tablets was higher than that from conventional hydroxypropyl methylcellulose (HPMC) based matrices, without any incorporated acidic additives.