Subcutaneous administration of nano- and microsuspensions of poorly soluble compounds to rats

The aim of the present study was to evaluate and interpret the pharmacokinetic profiles of two compounds after subcutaneous (s.c.) administration. The compounds have similar physicochemical properties, but are a base (BA99) and an acid (AC88), respectively. The compounds were administered as nano- (5 and 500?µmol/kg) and microsuspensions (5?µmol/kg) s.c. to Sprague–Dawley rats. At the low dose, the exposure was higher for both compounds administered as nanocrystals compared to microparticles. The high dose of the compounds resulted in even higher exposure, but not in a dose-linear manner. The differences in exposure between nano- and microparticles were mainly ascribed to higher dissolution rate and improved solubility for smaller particles. In addition to differences in exposure, there were also differences in the elimination pattern. After s.c. injection of 5?µmol/kg of BA99 as nano- and microsuspensions, the elimination profile was similar as observed earlier after oral administration. However, after injection of the higher dose of BA99 and all formulations of AC88, an extended elimination profile was observed, forming a maintained plateau under the investigated time-period. Essentially, constant plasma levels were caused by a balanced equilibrium between total body clearance of the drug and supply rate of drug from the formulations.     

Particle size reduction for improvement of oral absorption of the poorly soluble drug UG558 in rats during early development

Background: The exposure of UG558 was not good enough using traditional microsuspensions. Aim: The aim of this study was to find out whether nanosuspensions were a better choice compared with a microsuspension, for an acidic substance with a water solubility in the order of 2 μM (pH 6.8, small intestinal pH) and no permeability limitations. Methods: UG558 was ground by a planetary ball mill. The particle size was measured by laser diffraction and the stability of the particle sizes was followed. The pharmacokinetic parameters of UG558 administered as nanosuspension have been compared with those from microsuspension using rat as in vivo specie. Both formulations were administered orally. The nanosuspension was also administered intravenously. Results: The particle size of the nanosuspensions was about 190 nm and about 12 μm for the microsuspensions. At the administered doses, solutions were no alternative (e.g. due to limited solubility). Already at the lowest dose, 5 μmol/kg (5 ml/kg), a significant difference was observed between the two suspensions. These results were further confirmed at a high dose (500 μmol/kg, 5 mL/kg). Thus, the study demonstrated a clear correlation between particle size and in vivo exposures, where the nanosuspensions provided the highest exposure. Furthermore, no adverse events were observed for the substance nor the nanosuspension formulations (i.e., the particles) in spite of the higher exposures obtained with the nanoparticles. To make it possible to calculate the bioavailability, 5 μmol/kg doses of the nanosuspensions (5 ml/kg) were also administered intravenously. No adverse events were observed. Conclusions: The nanoparticles have a larger surface, resulting in faster in vivo dissolution rate, faster absorption, and increased bioavailability, compared to microparticles. The lower overall bioavailability observed at the high dose, compared with the low dose, was due to a combination of low dissolution rate, low solubility, and a narrow intestinal absorption window for UG558.     

Evaluation of exposure properties after injection of nanosuspensions and microsuspenions into the intraperitoneal space in rats

In the present paper, BA99 and AC88 were used as model compounds for intraperitoneal (i.p.) administration to Sprague-Dawley rats. A major problem for the compounds, like many others newly developed pharmaceutical drugs, is the poor solubility in water. To solve solubility related problems, development of nanosuspensions is an attractive alternative. Both compounds are suitable for nanosuspensions, using the milling approach. After 2 weeks in freezer, the nanoparticles aggregated to form particles in the 400–2000?nm interval. However, following a 20 s ultrasonication step, the original particle sizes (about 200?nm) were obtained. Adding 5% mannitol before the samples were frozen abolished aggregation. It is also possible to freeze-dry the nanosuspension in the presence of 5% mannitol and re-disperse the formulation in water. Nanosuspensions of both compounds were injected i.p. to rats at 5 and 500 µmoL/kg. At the low dose, also a microsuspension was administered. I.p. administration resulted in overall improved C_max for both AC88 and BA99 compared to s.c. and oral administration. I.p. is the preferred route of administration of tolerable drugs when a fast onset of action is desired and when a significant first passage metabolism occurs. The net charge of the active molecule appeared to affect the absorption kinetics. In the present work, the neutral molecule was favored over the negatively charged one.     

Nanosuspension formulations for low-soluble drugs: pharmacokinetic evaluation using spironolactone as model compound

Various particle sizes of spironolactone as a model low solubility drug were formulated to yield micro-and nanosuspensions of the type solid lipid nanoparticles and DissoCubes. Seven oral and one i.v. formulations were tested in an in vivo pharmacokinetic study in rats with the aim of characterizing the bioavailability of spironolactone on the basis of its metabolites canrenone and 7-alpha-thiomethylspirolactone. In addition, a dose escalation study was carried out using nonmicronized spironolactone suspension as well as a nanosuspension type DissoCubes. On the basis of AUC as well as Cmax ratios, three groups of formulations were distinguished. The biggest improvement was seen with a solid lipid nanoparticle formulation yielding a 5.7-fold increase in AUC for canrenone and a similar improvement based on the Cmax metric, followed by a group of three formulations containing nanosized, micronized, and coarse drug material and surfactant. The DissoCubes nanosuspension yielded highly significant improvements in bioavailability averaging 3.3-fold in AUC and 3.0-fold in terms of Cmax for canrenone. The third class encompasses all other formulations, which showed very little to no improvement in bioavailability. The results show that the particle size minimization was not the major determining factor in the bioavailability improvement. Rather, the type of surfactant used as stabilizer in the formulations was of greater importance. Improvement in drug solubility in the intestine as well as in dissolution rate of spironolactone are the most likely mechanisms responsible for the observed effect, although additional mechanisms such as permeability enhancement may also be involved.     

Pharmacokinetics and tissue distribution of amphotericin B following oral administration of three lipid-based formulations to rats

The objective of this study was to assess the pharmacokinetics and tissue distribution of amphotericin B (AmB) in rats following oral administration of three lipid-based formulations (iCo-009, iCo-010 and iCo-011). The lipid-based formulations were administered to rats at a dose of 10?mg/kg and blood samples were withdrawn at predose, 1, 2, 4, 6, 8, 10, 12, 24, 48 and 72?h, after which the animals were sacrificed and the body organs were collected for AmB quantification using a validated HPLC method. Plasma pharmacokinetics parameters were determined using non-compartmental analysis. The disappearance of AmB from plasma was the slowest following the administration of iCo-010 with MRT of 63?h followed by iCo-009 then iCo-011 (36 and 27?h). The AUC_0-24h of iCo-009 and iCo-010 was 1.5–2-fold higher than that of iCo-011. The kidney exposure was comparable between iCo-009 and iCo-010 and was higher than that of iCo-011. The lung exposure was the highest following iCo-010 administration as compared to that of iCo-009. The distribution of AmB from plasma to tissues resulted in a high accumulation of AmB overtime with slow back-distribution to plasma. The pharmacokinetics profiles varied among the three formulations, despite the similarity in lipid composition between iCo-010 and iCo-011 and the presence of Peceol® as a common component in the formulations. The administration of oral iCo-010 could lead to higher steady state concentrations in the tissues after multiple dosing, which could lead to enhanced eradication of tissue borne fungal and parasitic infections.     

Use of sorbitol as pharmaceutical excipient in the present day formulations – issues and challenges for drug absorption and bioavailability

Sorbitol is a popular sugar alcohol which has been used as an excipient in formulations of various drugs. Although from a safety perspective the presence of sorbitol in drug formulations does not raise a concern, reports have emerged and these suggest that sorbitol in drug formulations may alter oral absorption and bioavailability of certain drugs. The focus of this article was to review the published literature of various drugs where pharmacokinetic data has been reported for the drug alone versus drug administered with sorbitol and provide perspectives on the pharmacokinetic findings. Interestingly, for BCS class I drugs such as theophylline, metoprolol, the oral absorption, and bioavailability were generally not affected by sorbitol. However, theophylline oral absorption and bioavailability were decreased when sustained release formulation was used in place of immediate release formulation. For drugs such as risperidone (BCS class II) and lamivudine and ranitidine (BCS class III), the solution formulations showed diminished oral bioavailability in presence of sorbitol, whereas cimetidine and acyclovir (BCS class III), did not show any changes in pharmacokinetic profiles due to sorbitol. Finally, the presence of activated charcoal with sorbitol showed different pharmacokinetic outcome for BCS class I and II drugs.     

Cress seed mucilage based buccal mucoadhesive gel of venlafaxine: in vivo,in vitro evaluation

Venlafaxine is a newer antipsychotic drug which shows first pass effect. Cress seed is also called as garden cress or green salad. This study examined the mechanical (gel strength, adhesiveness) and rheological properties of cress seed mucilage based gels that contain different ratios of carbopol 934 P (0.5–1.5%). In addition, diffusion of venlafaxine from gel formulations was evaluated. The selected formulation was further analyzed for pharmacokinetic parameters in rabbits. All formulations exhibited pseudoplastic flow with thixotropy. Formulation F5 showed the C_max of 24.19 ± 0.72 ng/ml by buccal route of administration and 17.98 ± 1.15 ng/ml by oral route of administration. The bioavailability of F5 by buccal route was 54.44% and that of by oral route was 39.60%. A combination of the cress seed mucilage and carbopol 934 P resulted in a prolonged and higher venlafaxine delivery by buccal route of administration.     

Improved oral delivery of paclitaxel following administration in nanoemulsion formulations

Nanoemulsion formulations were designed for enhancing the oral bioavailability of hydrophobic drugs. Paclitaxel was selected as a model hydrophobic drug, which is also a substrate for the P-glycoprotein efflux system. The oil-in-water (o/w) nanoemulsions were formulated with pine nut oil as the internal oil phase, egg lecithin as the primary emulsifier, and water as the external phase. Stearylamine and deoxycholic acid were used to impart positive and negative charge to the emulsions, respectively. Nanoemulsions were prepared by sonication method and characterized for particle size and surface charge. The control and nanoemulsion formulations with tritiated [3H]-paclitaxel were administered orally to female C57BL/6 mice and the distribution of the drug was examined. The formulated nanoemulsions had a particle size range of approximately 90-120 nm (laser diffraction method) and zeta potential values ranging from -56 mV to +34 mV. Following oral administration, a significantly higher concentration of paclitaxel was observed in the systemic circulation when administered in the nanoemulsion relative to control aqueous solution. The absorbed drug was found to be distributed in the liver, kidneys, and lungs. The results of this study suggest that nanoemulsions are promising novel formulations that can enhance the oral bioavailability of hydrophobic drugs, like paclitaxel.     

Spray drying of a poorly water-soluble drug nanosuspension for tablet preparation: formulation and process optimization with bioavailability evaluation

Spray drying experiments of an itraconazole nanosuspension were conducted to generate a dry nanocrystal powder which was subsequently formulated into a tablet formulation for direct compression. The nanosuspension was prepared by high pressure homogenization and characterized for particle-size distribution and surface morphology. A central composite statistical design approach was applied to identify the optimal drug-to-excipient ratio and spray drying temperature. It was demonstrated that the spray drying of a nanosuspension with a mannitol-to-drug mass ratio of 4.5 and at an inlet temperature of 120?°C resulted in a dry powder with the smallest increase in particle size as compared with that of the nanosuspension. X-ray diffraction results indicated that the crystalline structure of the drug was not altered during the spray-drying process. The tablet formulation was identified by determining the micromeritic properties such as flowability and compressibility of the powder mixtures composed of the spray dried nanocrystal powder and other commonly used direct compression excipients. The dissolution rate of the nanocrystal tablets was significantly enhanced and was found to be comparable to that of the marketed Sporanox®. No statistically significant difference in oral absorption between the nanocrystal tablets and Sporanox® capsules was found. In conclusion, the nanosuspension approach is feasible to improve the oral absorption of a BCS Class II drug in a tablet formulation and capable of achieving oral bioavailability equivalent to other well established oral absorption enhancement method.     

Pharmacokinetic, tissue distribution, and excretion of puerarin and puerarin-phospholipid complex in rats

Puerarin is a potential therapeutic agent for cardiovascular diseases. But its poor oral bioavailability restricts its clinical application. In present study, as an evaluation of a formulation to improve the bioavailability of the drug, puerarin and its phospholipid complex were given to rats by intragastrically (i.g.) administration to compare pharmacokinetic, tissue distribution, and excretion. Serum samples were obtained at designated times after a single oral dose of 400 mg/kg puerarin or its complex. Tissue samples (heart, liver, spleen, kidney, lung, and brain), urine, and feces were collected and analyzed by a sensitive and specific high performance liquid chromatography (HPLC) method after i.g. administration of puerarin or its phospholipid complex. Compartmental and non-compartmental analyses were applied to the serum concentration versus time data. Pharmacokinetic parameters were calculated using the 3P97 pharmacokinetic software package. An open two-compartment, first-order model was selected for pharmacokinetic modeling. The results showed that after i.g. administration of 400 mg/kg puerarin and its phospholipid complex (equivalent to 400 mg/kg of puerarin), the pharmacokinetic parameters of the two formulations were different. The serum concentrations reached peaks at 0.894 ± 0.521 h and 0.435 ± 0.261 h, respectively, indicating the complex was more readily absorbed in serum than puerarin. The maximum concentrations for puerarin and its complex were 1.367 ± 0.586 mg·L^-1 and 2.202 ± 1.28 mg·L^-1 and AUC were 5.779 ± 1.662 mg·h. L^-1 and 8.456 ± 0.44 mg·h L^-1, respectively, indicating a higher bioavailability for the complex. The widely distribution characteristics of puerarin and its complex in tissues post-i.g. administration was identical and in a descending order as follows: lung, kidney, liver, heart, spleen, and brain. However, the amount was different. Puerarin distribution was higher in heart, lung, and brain after administering the complex. The cumulative 72 h urinary excretion of puerarin after i.g. administration of puerarin and its complex accounted for 1.05%, 1.11% of the administered dose, respectively. The cumulative feces excretion of puerarin was 32.3% and 25.5%. To sum up, oral administration of puerarin phospholipid complex modified the pharmacokinetics and tissue distribution of puerarin and it could be an effective oral formulation for puerarin.     

Pharmacokinetics of Khellin in Rabbits: Oral,Intravenous, and Intramuscular Administrations

Abstract

This study was undertaken to investigate the pharmacokinetics of khellin in rabbits following oral, intravenous, and intramuscular administrations. Analysis of khellin in the plasma samples was performed according to a previously developed HPLC method. The data obtained from the rapid intravenous administration experiments fitted the two-compartment open model with β, α, total body clearance (TBC), and volume of central compartment (V_c) of 0.0306 hr^?1, 1.93 hr^?1, 573 ml. hr^?1.kg^?1, and 2.1 liter. kg^?1, respectively. The concentration-time profiles acquired following the administration of sugar-coated tablets of khellin were typical of sustained release formulations with time to peak concentration (t_max) and dose-normalized peak plasma concentration (C_max) of 21 hr and 23 ng. ml^?1.mg^?1.kg, respectively. With the exception of one animal, rapid absorption was obtained following the intramuscular or oral suspension administration with (t_max) ranging from 0.083 to 4 hr. A complete absorption was obtained with intramuscular injection, whereas, the fraction of dose absorbed following oral suspension administration was 38%.     

Production and in vitro characterization of solid dosage form incorporating drug nanoparticles

The objective of this study was to develop a tablet formulation of ketoconazole incorporating drug nanoparticles to enhance saturation solubility and dissolution velocity for enhancing bioavailability and reducing variability in systemic exposure. The bioavailability of ketoconazole is dissolution limited following oral administration. To enhance bioavailability and overcome variability in systemic exposure, a nanoparticle formulation of ketoconazole was developed. Ketoconazole nanoparticles were prepared using a media-milling technique. The nanosuspension was layered onto water-soluble carriers using a fluid bed processor. The nanosuspensions were characterized for particle size before and after layering onto water-soluble carriers. The saturation solubility and dissolution characteristics were investigated and compared with commercial ketoconazole formulation to ascertain the impact of particle size on drug dissolution. The drug nanoparticles were evaluated for solid-state transitions before and after milling using differential scanning calorimetry (DSC) and powder X-ray diffraction (PXRD). This study demonstrated that tablet formulation incorporating ketoconazole nanoparticles showed significantly faster rate of drug dissolution in a discriminating dissolution medium as compared with commercially available tablet formulation. There was no affect on solid-state properties of ketoconazole following milling. The manufacturing process used is relatively simple and scalable indicating general applicability to enhance dissolution and bioavailability of many sparingly soluble compounds.     

Pharmacokinetic evaluation and antitumor activity of 2-methoxyestradiol nanosuspension

The aim of the present study was to evaluate the pharmacokinetic and antitumor activity of 2-methoxyestradiol (2-ME) nanosuspension relative to 2-ME solution both in vitro and in vivo. The pharmacokinetics of 2-ME administered either as a nanosuspension or as a solution were compared after I.V. administration to rats. In plasma, 2-ME nanosuspension exhibited a significantly (p?相似文献   

Production and In Vitro Characterization of Solid Dosage form Incorporating Drug Nanoparticles

The objective of this study was to develop a tablet formulation of ketoconazole incorporating drug nanoparticles to enhance saturation solubility and dissolution velocity for enhancing bioavailability and reducing variability in systemic exposure. The bioavailability of ketoconazole is dissolution limited following oral administration. To enhance bioavailability and overcome variability in systemic exposure, a nanoparticle formulation of ketoconazole was developed. Ketoconazole nanoparticles were prepared using a media-milling technique. The nanosuspension was layered onto water-soluble carriers using a fluid bed processor. The nanosuspensions were characterized for particle size before and after layering onto water-soluble carriers. The saturation solubility and dissolution characteristics were investigated and compared with commercial ketoconazole formulation to ascertain the impact of particle size on drug dissolution. The drug nanoparticles were evaluated for solid-state transitions before and after milling using differential scanning calorimetry (DSC) and powder X-ray diffraction (PXRD). This study demonstrated that tablet formulation incorporating ketoconazole nanoparticles showed significantly faster rate of drug dissolution in a discriminating dissolution medium as compared with commercially available tablet formulation. There was no affect on solid-state properties of ketoconazole following milling. The manufacturing process used is relatively simple and scalable indicating general applicability to enhance dissolution and bioavailability of many sparingly soluble compounds.     

Disposition of 14C-Quinelorane in Dogs Following Oral or Intravenous Dosing and Transdermal Patch Application

A transdermal patch was developed to circumvent the emesis associated with the oral and intravenous administration of a dopamine agonist, quinelorane, to dogs.

Approximate steady-state plasma concentrations were achieved following the daily application of a transdermal patch for 7 days. Each dog received between 0.1 and 0.2 mg/kg per day from the transdermal patch.

At steady-state conditions, dogs received either a single oral dose of ¹⁴C-quinelorane at 0.1 mg/kg, a bolus intravenous dose of 0.03 mg/kg or had a transdermal patch containing the radioactive free base, ¹⁴C-quinelorane, applied to their abdomens for 24 hours; the approximate dose was 0.18 mg/kg.

The plasma pharmacokinetics were measured by liquid scintillation counting and ELISA.

The systemic bioavailability of quinelorane, as measured by the ELISA, was 30%, indicative of first-pass metabolism.

The radioactive urinary metabolite profile was similar for all three routes of administration. Principal entities in the urine were quinelorane, the N-despropyl- and the hydroxy-lactam- metabolites, accounting for 29, 25 and 3% of the dose, respectively. The major route of excretion of radioactivity was via. the urine, irrespective of the route by which the drug was administered.     

Disposition of 14C-Quinelorane in Dogs Following Oral or Intravenous Dosing and Transdermal Patch Application

Abstract

A transdermal patch was developed to circumvent the emesis associated with the oral and intravenous administration of a dopamine agonist, quinelorane, to dogs.

Approximate steady-state plasma concentrations were achieved following the daily application of a transdermal patch for 7 days. Each dog received between 0.1 and 0.2 mg/kg per day from the transdermal patch.

At steady-state conditions, dogs received either a single oral dose of ¹⁴C-quinelorane at 0.1 mg/kg, a bolus intravenous dose of 0.03 mg/kg or had a transdermal patch containing the radioactive free base, ¹⁴C-quinelorane, applied to their abdomens for 24 hours; the approximate dose was 0.18 mg/kg.

The plasma pharmacokinetics were measured by liquid scintillation counting and ELISA.

The systemic bioavailability of quinelorane, as measured by the ELISA, was 30%, indicative of first-pass metabolism.

The radioactive urinary metabolite profile was similar for all three routes of administration. Principal entities in the urine were quinelorane, the N-despropyl- and the hydroxy-lactam- metabolites, accounting for 29, 25 and 3% of the dose, respectively. The major route of excretion of radioactivity was via. the urine, irrespective of the route by which the drug was administered.     

Effect of excipient and processing variables on adhesive properties and release profile of pentoxifylline from mucoadhesive tablets

The bioavailability and onset of action of drugs with high first-pass metabolism can be significantly improved by administration via the sublingual route. The objective of this study was to evaluate the effect of polymer type and tablet compaction parameters on the adhesive properties and drug release profile from mucoadhesive sublingual tablet formulations. Pentoxifylline was selected as the model drug because it has poor oral bioavailability due to extensive first-pass metabolism. Two polymers known to possess mucoadhesive properties, carbomer and hydroxypropyl methyl cellulose (HPMC), were used to prepare the formulations. Tablets were prepared by using direct compression technique and evaluated for in vitro dissolution, drug-excipient interactions, and adhesive properties. In general, there was a decrease in the rate of drug release with an increase in the concentration of polymers. No drug-excipient interactions were evident from differential scanning calorimetry or high-performance liquid chromatography analysis. For the formulations containing HPMC, the force of mucoadhesion increased with an increase in the concentration of polymer; however, for carbomer formulations, no such correlation was observed. Force of mucoadhesion decreased as a function of hydration time in both of the polymers.     

Effect of Excipient and Processing Variables on Adhesive Properties and Release Profile of Pentoxifylline From Mucoadhesive Tablets

ABSTRACT

The bioavailability and onset of action of drugs with high first-pass metabolism can be significantly improved by administration via the sublingual route. The objective of this study was to evaluate the effect of polymer type and tablet compaction parameters on the adhesive properties and drug release profile from mucoadhesive sublingual tablet formulations. Pentoxifylline was selected as the model drug because it has poor oral bioavailability due to extensive first-pass metabolism. Two polymers known to possess mucoadhesive properties, carbomer and hydroxypropyl methyl cellulose (HPMC), were used to prepare the formulations. Tablets were prepared by using direct compression technique and evaluated for in vitro dissolution, drug-excipient interactions, and adhesive properties. In general, there was a decrease in the rate of drug release with an increase in the concentration of polymers. No drug-excipient interactions were evident from differential scanning calorimetry or high-performance liquid chromatography analysis. For the formulations containing HPMC, the force of mucoadhesion increased with an increase in the concentration of polymer; however, for carbomer formulations, no such correlation was observed. Force of mucoadhesion decreased as a function of hydration time in both of the polymers.     

Combined site-specific release retardant mini-matrix tablets (C-SSRRMT) for extended oral delivery of dexketoprofen trometamol: in vitro evaluation and single versus multiple doses pharmacokinetic study in human volunteers

Abstract

Development of extended release oral formulations of dexketoprofen trometamol (DT), a rapidly eliminated drug with high solubility, poses a great challenge especially when a portion of the dose is to be absorbed from the colon. In this study, site-specific release-retardant mini-matrix tablets (SSRRMTs) were developed and functionally coated with pH-responsive materials to achieve a site-specific delivery of DT at the duodenojejunal (DSRRMT) and ileocecal (ISRRMT) regions. Stomach-specific coated mini-tablets (SSCMTs) were manufactured for immediate release of about 16% of the daily dose of DT in the stomach. The SSCMT, DSRRMT, and ISRRMT were combined into a solid dosage form (C-SSRRMT tablets or capsules) to achieve the required linear release profile for once daily administration of DT. The SSRRMT and C-SSRRMT formulations were evaluated for the physical properties, in vitro-disintegration and in vitro dissolution and proved to be consistent with the pharmacopeial specifications. The in vitro release profiles of both C-SSRRMT tablets and capsules showed a constant release rate of about 6?mg/h and were similar to that of the theoretical target linear release profile. The pharmacokinetic study using human volunteers showed the bioequivalence of a single oral dose of C-SSRRMT capsules compared to three-successive oral doses of the immediate release market tablets with less ups and downs in the drug levels. The C-SSRRMT capsules formulation, may therefore, constitute an advance in the extended oral delivery of DT without the lack of efficacy and the adverse events frequently encountered in multiple daily dosing of the immediate release tablets.