Effect of process variables on the microencapsulation of vitamin A palmitate by gelatin-acacia coacervation.

Microcapsules of vitamin A palmitate were prepared by gelatin-acacia complex coacervation. The effects of colloid mixing ratio, core-to-wall ratio, hardening agent, concentration of core solution, and drying method on the coacervation process and the properties of the microcapsules were investigated. The microcapsules of vitamin A palmitate were prepared using different weight ratios of gelatin and acacia, that is, 2:3, 1:1, and 3:2 under controlled conditions. The other factors studied were 1:1, 1:2, and 1:3 core-to-wall ratios; 30, 60, and 120 min of hardening time; 2, 5, and 10 ml of formaldehyde per 280 g of coacervation system as a hardening agent; and 30%, 40%, and 50% w/w vitamin A palmitate in corn oil as a core material. The drying methods used were air drying, hot air at 40 degrees C, and freeze-drying. The results showed that spherical microcapsules were obtainedfor all conditions except for 30 min of hardening time, which did not result in microcapsules. The optimum conditions for free-flowing microcapsules with a high percentage of entrapped drug were 1:1 gelatin-to-acacia ratio and 1:2 core-to-wall ratio when hardening with 2 ml formaldehyde for 60 min and using 40% w/w vitamin A palmitate in corn oil as the core concentration. In addition, drying the microcapsules by freeze-drying provided microcapsules with excellent appearance.

Preformulation studies on the S-isomer of oxybutynin hydrochloride, an Improved Chemical Entity (ICE).

(S)-Oxybutynin HCl (S-OXY) is a white crystalline solid powder with an acicular particle morphology. Differential scanning calorimetry (DSC) thermograms revealed one characteristic endotherm at 116.2 degrees C. On rescanning a sample heated to 120 degrees C, no thermal events were distinguished in the temperature range 25 degrees C to 150 degrees C. Weight loss curves determined by thermogravimetric analysis showed a continuous, gradual weight loss of about 0.15% over the temperature range 30 degrees C to 110 degrees C, followed by a change in slope and more rapid weight loss beginning at 150 degrees C. Observation by hot-stage microscopy confirmed the melting endotherm observed by DSC. Equilibrium moisture uptake studies indicated low water vapor uptake at low relative humidities (<52.8%). At relative humidities of 75.3% and 84.3%, S-OXY first deliquesced and then converted to a lower melting point crystal form. X-ray powder diffraction (XRPD) data supported the DSC findings. S-OXY underwent degradation by ester hydrolysis at alkaline pHs. The kinetics of this reaction were studied at 25 degrees C in carbonate-bicarbonate buffers. Observed rate constants of 0.008 h(-1) and 0.0552 h(-1) were determined at pH 9.69 and 10.25, respectively. The pKa of S-OXY was 7.75. The aqueous solubility of S-OXY was described as a function of pH and the free-base solubility. The mean partition coefficient log P was 3.33 using 1-octanol. The surface tensions of aqueous solutions of S-OXY decreased with increasing concentration, but no concentration-independent region was observed, indicating that S-OXY does notform micelles in aqueous solution. The dissolution rate of S-OXY from a compressed disk in 0.1 N HCl was rapid, whereas it was considerably slower at pH 7.4. Addition of 1% hexadecyltrimethylammonium bromide (CTAB) at pH 7.4 significantly improved the dissolution rate. S-OXY displayed very poor flow properties when compared to standard pharmaceutical excipients. XRPD results indicated that S-OXY exhibited a loss in crystallinity following ball milling. Hiestand tableting indices indicated that S-OXY has good bonding properties andforms strong compacts, but is likely to be susceptible to capping on ejection from the die. This indicated the needfor a plastically deformable excipient such as Avicel PH-101 in tablet formulations.

Development of a lyophilized formulation for (R,R)-formoterol (L)-tartrate.

(R,R)-formoterol is a beta-agonist for inhalation. Aqueous instability suggested the need for a reconstitutable lyophilized dosage form. The objective of these studies was to devise a stable, rapid-dissolving, therapeutically compatible dosage form. The effects of diluents and residual moisture on the stability of thermally stressed formoterol formulations were investigated. Drug and various excipients (acetate, lactose, and mannitol) were lyophilized and placed in humidity chambers (0 to 90% relative humidity) at 25 to 50 degrees C. Stability was characterized by time-dependent changes using HPLC, pH, and XRD. Residual moisture were determined by Karl Fisher methods. Regression models were developed to quantify the effects of formulation and environmental variation on drug stability. Solid-state instability was observed as a function of high residual moisture and diluent type. Although the residual moisture in mannitol formulations were typically below 1%, the degradation rate (50 degrees C) varied from 2 to 10 mcg/day, which was 1.3- to 20-fold high than observed for lactose formulations under the same relative humidity conditions. At high relative humidity, the presence of acetate significantly increased the degradation rate (p < 0.04). The critical residual moisture content for lactose formulations was 3%. The amount of lactose was optimized by evaluating the degradation over the temperature range 25 to 50 degrees C. Mannitol and acetate were shown to be unsuitable excipients, and an optimal lactose amount was 50 mg for vials containing 50 mcg of drug.

Prediction of adsorption from multicomponent solutions by activated carbon using single-solute parameters.

The adsorption of 3 barbiturates--phenobarbital, mephobarbital, and primidone--from simulated intestinal fluid (SIF), without pancreatin, by activated carbon was studied using the rotating bottle method. The concentrations of each drug remaining in solution at equilibrium were determined with the aid of a high-performance liquid chromatography (HPLC) system employing a reversed-phase column. The competitive Langmuir-like model, the modified competitive Langmuir-like model, and the LeVan-Vermeulen model were each fit to the data. Excellent agreement was obtained between the experimental and predicted data using the modified competitive Langmuir-like model and the LeVan-Vermeulen model. The agreement obtained from the original competitive Langmuir-like model was less satisfactory. These observations are not surprising because the competitive Langmuir-like model assumes that the capacities of the adsorbates are equal, while the other 2 models take into account the differences in the capacities of the components. The results of these studies indicate that the adsorbates employed are competing for the same binding sites on the activated carbon surface. The results also demonstrate that it is possible to accurately predict multicomponent adsorption isotherms using only single-solute isotherm parameters. Such prediction is likely to be useful for improving in vivo/in vitro correlations.

The effect of polymorphism on powder compaction and dissolution properties of chemically equivalent oxytetracycline hydrochloride powders.

In South Africa, oxytetracycline is identified as an essential drug; many generic products are on the market, and many more are being developed. In this study, six oxytetracycline hydrochloride powders were obtained randomly from manufacturers, and suppliers were compared. It was found that compliance to a pharmacopoeial monograph was insufficient to ensure the optimum dissolution performance of a simple tablet formulation. Comparative physicochemical raw material analysis showed no major differences with regard to differential scanning calorimetry (DSC), infrared (IR) spectroscopy, powder dissolution, and particle size. However, the samples could be divided into two distinct types with respect to X-ray powder diffraction (XRD) and thus polymorphism. The two polymorphic forms had different dissolution properties in water or 0.1 N hydrochloride acid. This difference became substantial when the dissolution from tablets was compared. The powders containing form A were less soluble than that containing form B.

Prediction of the Hiestand bonding indices of binary powder mixtures from single-component bonding indices.

A priori predictions of the bonding indices of binary powder mixtures from the single-component indices were attempted. The binary mixtures were classified according to the mechanism of deformation of the single-components as plastic-plastic, brittle-brittle, and plastic-brittle. When the components of a binary mixture consolidated by the same mechanism (plastic-plastic and brittle-brittle mixtures), a straight line could be fit to a plot of bonding index versus composition. This linearity indicates that the bonding index can be reliably estimated by interpolation between the two single-component bonding indices. When the mixtures were such that one component was brittle while the other was plastic, a linear function did not fit the data. For these cases, a second-degree polynomial equation could be fit to a plot of bonding index versus composition. A combination of multiple linear regression and trial and error was used to generate a single generalized equation. For pairs of compounds wherein each compound has a different compaction mechanism, this new equation appears to allow satisfactory predictions of the bonding indices of mixtures with varying compositions using only the single-component bonding indices.

Use of Fourier transform infrared (FTIR) spectroscopy to follow the adsorption of heptane and 1,4-dioxane vapors on a zinc oxide surface.

Vapor adsorption isotherms of two nonpolar model compounds, heptane and 1,4-dioxane, were determined for a very small particle size zinc oxide (ZnO) powder (median particle size approximately 23 nm) in the lower relative vapor pressure (P/Po) region. The ZnO samples for all adsorption measurements were dried at 400 degrees C for 4 h. A new method, which employed an FTIR spectrometer with a long path gas cell (IR path length of 3.0 m), was developed for the organic vapor adsorption measurements. The amount adsorbed was determined by mass balance. This method allows accurate quantification of organic vapors and is sensitive to very low P/Po values. The heptane and 1, 4-dioxane vapor adsorption isotherms appeared to exhibit the expected Type II behavior. The surface areas obtained for ZnO from BET analyses of the heptane and 1,4-dioxane vapor adsorption isotherms (36.9 and 30.3 m2/g) compared reasonably well to the surface area obtained from BET analysis of the nitrogen vapor adsorption isotherm (32.6 m2/g). The amount of vapor adsorbed by ZnO at P/Po equal to 0.1, in terms of number of moles, was observed to decrease in the order: water10 >> 1,4-dioxane > heptane. It was inferred that, while heptane was only adsorbed via a dipole-induced dipole interaction, 1,4-dioxane was physically adsorbed via an interaction dominated by the oxygen lone-pair orbital. Presumably, this interaction was more comparable to a weak dipole-dipole interaction. These results are consistent with the expected strengths of interaction.

Significance of melanin binding and metabolism in the activity of 5-acetoxyacetylimino-4-methyl-delta2-1,3,4,-thiadiazolin e-2-sulfonamide.

5-Acetoxyacetylimino-4-methyl-delta2-1,3,4,-thiadiazoline -2-sulfonamide (compound (1)) is an ester prodrug that lowered intraocular pressure (IOP) in albino New Zealand rabbits, but was found to be inactive in pigmented Dutch Belt rabbits. In order to explain the differences in pharmacological activity for the two rabbit species, metabolism and melanin binding were studied. Depending on the initial concentration, the binding of compound (1) to natural melanin (Sepia officinalis) was 20-60%. The binding constant, K, at 37 degrees C was 4.32 x 10(5) M(-1) and the maximum moles bound to melanin, r(max), was 4.5 x 10(-7) mol/mg of melanin. From a determination of binding at temperatures between 25 degrees C and 47 degrees C, a van't Hoff plot was constructed to determine enthalpy and entropy changes accompanying the binding process, deltaH and deltaS, respectively. Values calculated from the plot were -12.7 and -15.4 kcal/(mol deg), respectively. Negative values for these parameters are consistent with charge transfer interactions and therefore suggest that this may be an operative mechanism between compound (1) and melanin. The in vitro incubation of compound (1) was also studied with various ocular tissues from both albino and pigmented rabbits which were iris-ciliary body, intact cornea, stroma/endothelium and aqueous humor. A major metabolite, MET 1, was identified and also observed from in vivo analyses of the same tissues following topical application. The metabolite was isolated and subjected to mass spectroscopy and proton nuclear magnetic resonance spectroscopy analysis. From these analyses, it was hypothesized that the formation of MET 1 involved a GSH conjugation mechanism which displaced the sufonamide (-SO2NH2) group. The metabolism was found to be less extensive in the pigmented rabbit than in the albino rabbit and suggested that the binding affinity of compound (1) for melanin was a better explanation for the lack of IOP activity in the pigmented rabbit than differences in metabolism.

Stability of undiluted and diluted adenosine at three temperatures in syringes and bags.

The stability of adenosine in various diluents in polypropylene syringes and polyvinyl chloride (PVC) bags at three temperatures was studied. Portions of pooled undiluted adenosine infusion (3 mg/ mL) were stored in 60-mL capped syringes, 20 for each storage condition. Adenosine infusions were prepared by mixing adenosine with 5% dextrose injection, 0.9% sodium chloride injection, lactated Ringer's injection, or 5% dextrose and lactated Ringer's injection to produce a concentration of 0.75 mg/mL. Samples of each infusion were stored in 60-mL capped syringes and 50-mL bags, 20 syringes and 20 bags for each storage condition. Syringes and bags were stored in the dark at 25, 5, and -15 degrees C. At various sampling times, three syringes and three bags of each infusion were removed for visual inspection, pH measurement, and high-performance liquid chromatographic analysis. At 10 and 16 days, fungal growth at 25 degrees C was suspected in the infusions prepared with 5% dextrose injection. For all other samples, there was no evidence of precipitation or change in pH. The concentration of adenosine remained constant in all samples at all storage conditions. Adenosine 3 mg/mL was stable in polypropylene syringes for 7 days at 25 degrees C, 14 days at 5 degrees C, and 28 days at -15 degrees C; adenosine 0.75 mg/ mL in 0.9% sodium chloride injection and in 5% dextrose injection was stable in polypropylene syringes and PVC bags for 16 days at 25, 5, and -15 degrees C; and adenosine 0.75 mg/mL in lactated Ringer's injection and in 5% dextrose and lactated Ringer's injection was stable in syringes and bags for 14 days at 25, 5, and -15 degrees C.

The influence of tear proteins on the film stability of rabbit tear extracts.

This study was undertaken to gain an understanding of the significance of tear proteins in stabilizing the tear film. Either a sigma agonist, N,N-dimethyl-2-phenylethylamine HCl (AF2975), or a sigma antagonist, haloperidol, was administered to rabbit eyes in order to increase or decrease protein secretion, respectively. At 0, 10 and 60 minutes after instillation, tear proteins were extracted from Schirmer strips and measured for total protein. A portion of the extract was used for separating five major protein fractions using size-exclusion HPLC. Total protein extract or individual protein fractions were measured for surface tension by the horizontal capillary method and for in vitro break up time (in vitro BUT), a newly designed procedure. A statistically significant decrease was measured for surface tension and a concomitant increase was measured for in vitro BUT for the total protein samples at 10 and 60 minutes after instillation of AF2975 compared to the vehicle treated eye. The results for haloperidol yielded an increase in surface tension and an decrease in in vitro BUT. When the tear proteins were separated into five major fractions, only the 23 minute protein fraction was found to decrease surface tension and increase in vitro BUT following AF2975 administration. Haloperidol, a sigma antagonist, showed an exact opposite effect for the total protein and the 23 minute protein fraction.

Tear film stability of protein extracts from dry eye patients administered a sigma agonist.

Fourteen dry eye volunteers placed one to two drops of 0.15% AF2975 (N,N-dimethyl-2-phenylethylamine HCl) in one eye and the vehicle in their other eye four times a day for 21 days. AF2975 is a sigma agonist known to stimulate the release of tear proteins after instillation in rabbit eyes and was tested for its ability to stabilize protein film extracted from dry eye volunteers. After day 7 and again after day 21, Schirmer test strips were inserted in each eye for 5 minutes, measured for wetting, and stored at -20 degrees C for protein analysis. A volume of 600 microliters was used to extract total protein. A portion of the extract was analyzed for total protein. The remainder was used to measure surface tension, to determine in vitro break up time (in vitro BUT) in a newly designed apparatus, and to further analyze for tear lipocalin, formerly known as presystemic tear albumin. Statistically significant differences were obtained between the drug treated eye and the vehicle treated eye for measurements determined for days 7 and 21. Tear extracts from the drug treated eye showed statistically significant decreases in surface tension and increases in in vitro BUT. Extracts from the drug treated eye also showed statistically significant increases in protein content and tear lipocalin. The results suggest that AF2975 may be able to stabilize the tear film by increasing the concentration of proteins in human tears.

Determination of diffusion coefficients of sodium p-aminosalicylate in sheep nasal mucosae and dialysis membranes by Fourier transform infrared horizontal attenuated total reflectance spectroscopy.

Fourier transform infrared horizontal attentuated total reflectance (FT-IR-H-ATR) spectroscopy was employed to determine the diffusion coefficients of sodium p-aminosalicylate (PAS) in sheep nasal mucosae and dialysis membranes. The system configuration, which comprises a closed system with an aqueous layer and a membrane layer, represents diffusion from a solution of limited volume. Data analysis involved fitting a truncated (seven term) Fourier series to the total mass transport into the membrane as a function of time. Comparison of diffusion coefficients of PAS in dialysis membranes obtained by this technique to those obtained by a standard steady-state permeation method showed excellent agreement. Apparent diffusion coefficients were approximately 4.33 (+/- 0.38) x 10(-7) and approximately 9.62 (+/- 5.30) x 10(-7) cm2/s for dialysis membranes and sheep nasal mucosae, respectively. These values are substantially smaller than the diffusion coefficient of PAS in aqueous solution, indicating that the rate-limiting step was diffusion in the membrane. The effect of purified gastric mucin solution (concentration up to approximately 6% w/v) on the apparent diffusion coefficient of PAS in the membranes was also investigated. The results showed no statistically significant change in the apparent diffusion coefficient in the presence of mucin for either sheep nasal mucosae or dialysis membranes. Although it was reported that mucin in solution retards the diffusion of PAS as compared to buffer alone, the mass transport within the membrane was the rate-limiting step for this hydrophilic compound.

The effect of composition on the tableting indices of binary powder mixtures.

The purpose of this study was to investigate the effect of the composition of a binary powder mixture on the bonding index, the brittle fracture index, and the strain index, as defined by Hiestand. The studies involved tensile strength and dynamic indentation hardness determinations of square compacts, the solid fractions of which were 0.83. The mixtures were such that both components consolidated by plastic deformation, both components consolidated by brittle fracture, or one component was brittle while the other was plastic. The measured quantities were then used to compute the bonding index, the brittle fracture index, and the strain index. The bonding indices and tensile strengths of the individual plastic materials were greater than those of the individual brittle materials. It was concluded that the bonding indices were linearly related to composition when both materials consolidated by the same mechanism. It was further concluded that the bonding indices were related to compact composition by a second-degree polynomial equation for mixtures with one brittle and one plastic component. This latter relationship was consistent for four pairs of components.

Determination of the mechanism for the decrease in zinc oxide surface area upon high-temperature drying.

High-temperature drying is required to remove chemisorbed water from the zinc oxide surface. High-temperature drying of a very small particle size zinc oxide powder (median particle size approximately 23 nm) resulted in a substantial decrease in the surface area. The surface areas (BET analysis of 77 K nitrogen vapor adsorption data) of ZnO samples dried at 500 degrees C decreased continually as the drying time was increased. Although the surface area decrease was fastest during the first 5 h, a 64% decrease in surface area was found after 20 h. The decrease in surface area was not due to a collapse of pore structure. Comparison of nitrogen vapor adsorption and desorption isotherms as well as geometric calculations of surface area indicated that both the original and final particles were nonporous. X-ray diffractograms of the original powder and of powders dried at two temperatures were all identical. Thus, no change in crystal structure occurred as a result of drying at 500 degrees C. Atomic force microscopy provided substantial evidence that the surface area decrease was due to a shift in the particle size distribution to a larger mean size. It was verified using two different experiments that ZnO exhibited significant sublimation at 500 degrees C. It was concluded that the increase in particle size was due to a sublimation/condensation process that obeyed the Kelvin equation. The effect of ZnO particle size on the vapor pressure ratio in the Kelvin equation was modeled at 500 degrees C for several different assumed solid surface tensions. Drying conditions for ZnO were then selected which balanced maximum removal of chemisorbed water and minimum surface area decrease. Water vapor adsorption isotherms for ZnO at 25 degrees C were subsequently obtained. Differences in the isotherms resulting from the presence or absence of a chemisorption contribution could clearly be demonstrated.

Pressure-induced activity loss in solid state catalase.

The pressure-induced reductions in the activities of a number of enzymes in the solution state, and more recently in the solid state, have been reported. To further investigate the effect of pressure on proteins in the solid state, the enzyme catalase was used as a model. Compacts containing 150.0 +/- 0.2 mg of catalase powder were prepared on instrumented laboratory presses using various compaction pressures between 0 and 669 MPa. After compaction, a spectrophotometric assay was utilized to determine the pseudo-first-order rate constants for the catalase-catalyzed decomposition of hydrogen peroxide. These rate constants were used to calculate the change in catalase activity. Results indicated a loss in catalase activity of up to 30% at compaction pressures of 251 MPa or greater. While the mechanism which produces the loss of enzyme activity is not clear, a strong linear correlation between enzyme activity and compaction pressure was seen over the range of pressures (0-251 MPa) where the decrease in activity occurred. In addition, compact densities were calculated and correlated to enzyme activity values. This correlation did not appear to be as strong.

Computer modeling of adsorption on an activated charcoal surface.

The molecular modeling program SYBYL was used to simulate the adsorption of various barbiturates by an activated charcoal surface. The compounds barbituric acid (BA), barbital (B), phenobarbital (PB), mephobarbital (M), and primidone (Pr) were modeled, and their structures were energetically minimized. These structures agreed with literature reports for the conformations of these molecules in dimethyl sulfoxide-d6, methanol-d4, and chloroform-d. The activated charcoal surface was modeled using graphitic crystallites which had either no oxygen-containing functional group, a C-OH functional group, or a C = O functional group. The presence of the C-O (presumably C-OH) and C = O functional states on activated charcoal surfaces had been previously determined by X-ray photoelectron spectroscopy. It was assumed that the crystallite was locally flat. Upon docking, conformational changes were observed for barbital, phenobarbital, mephobarbital, and primidone. Estimates for the heat of adsorption ranged from -62.3 kJ/mol for barbituric acid to -91.1 kJ/mol for mephobarbital on the hydroxylated surface. Allowance for the heat of desorption of the required number of water molecules from the surface, also determined by SYBYL, gave heat of displacement values of -19.4 kJ/mol for barbituric acid and -32.6 kJ/mol for mephobarbital. These values compared well to the heat of displacement values obtained by isoperibol calorimetry, which were -20.3 kJ/mol for barbituric acid and -31.6 kJ/mol for mephobarbital. Previous laboratory studies had demonstrated the greater importance of the C-O functional state for barbiturate adsorption compared to the C = O functional state. The computer-modeled system predicted the same result.

The use of Fourier transform infrared (FT-IR) spectroscopy to determine the diffusion coefficients of alcohols in polydimethylsiloxane.

A variable long path gas cell was used to measure the sorption of organic vapors by a polymer slab. Unfilled polydimethylsiloxane (PDMS) slabs were cast and used to study the sorption of a series of aliphatic alcohols. The PDMS slab was suspended in the gas cell and exposed to low relative pressures of an alcohol vapor. The sorption rate of the alcohol vapor by the PDMS slab was obtained by measuring the decrease in the amount of free diffusant in the gas cell. The diffusion coefficients of the alcohols in the PDMS slab were then calculated from the curves of amount of diffusant sorbed versus time. The results show that the values of the diffusion coefficients at nearly infinite dilution, D0, for methanol, ethanol, 1-propanol, and 1-butanol are 1.01 x 10(-5), 0.61 x 10(-5), 0.54 x 10(-5), and 0.33 x 10(-5) cm2/sec, respectively. The isotherms for the sorption of the alcohols by the PDMS slab were also constructed from the data.

Phenobarbital removal characteristics of three brands of activated charcoals: a system analysis approach.

The in vivo phenobarbital removal characteristics of three brands of activated charcoal (Actidose, Charcoaid, Superchar) were studied in normal volunteers using a system analysis approach. The subjects received a 200-mg dose of oral or intravenous phenobarbital followed by a single oral dose of 30 g of one of the three charcoals in a randomized crossover design. The relative merits of the three charcoals in enhancing the removal of oral and intravenous phenobarbital were assessed using a system analysis approach. The removal clearance, time to peak (tp), peak removal clearance (Rmax), percentage of dose removed (PCT infinity), and phenobarbital removal clearance (CLr) were calculated for the oral and intravenous treatments. Superchar had a pulse-like effect, with the shortest tp and the largest Rmax. Actidose and Charcoaid had similar effects, with Actidose inducing slightly greater phenobarbital removal. Superchar has the highest surface area and relative percentage of surface hydroxyl groups, whereas Actidose has the lowest surface area and relative percentage of surface hydroxyl groups of the three charcoals studied. Although correlations between the in vitro and the in vivo phenobarbital adsorption characteristics of the three charcoals may be difficult due to the presence of preservatives and palatibility enhancers in the commercial preparations, it appears that the in vivo effectiveness decreases as the surface area and the concentration of surface hydroxyl groups decrease. The proposed system analysis approach requires fewer assumptions than methods based on compartmental or physiologic approaches and has the advantage of describing the phenobarbital removal in a dynamic manner.