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.     

Co-administration of a nanosuspension of a poorly soluble basic compound and a solution of a proton pump inhibitor--the importance of gastrointestinal pH and solubility for the in vivo exposure

In Sigfridsson et al. (2011, Drug Dev Ind Pharm, 37:243-251), there was no difference in plasma concentration of BA99 when administering the drug as nanosuspension or microsuspension and analyzing the blood samples by liquid chromatography-mass spectrometry. This was related to the dissolved amount of drug in the gastric tract, which was high enough to support fast absorption when the drug reached the small intestine. One single physicochemical property (pK(a), about 3 for BA99) abolished the benefit of small particles. These results were further confirmed in the present study, where a proton pump inhibitor, AZD0865, was used to elevate the gastric pH and then drastically decreased the gastric solubility. In this way, BA99 could be considered as a model compound for a neutral substance. By increasing the gastric pH to 5-6 and 8-9, respectively, in rats, the plasma concentrations of BA99, after administering nanosuspensions, were unchanged compared with untreated (i.e. no AZD0865) animals. For microsuspensions of the test compound, on the other hand, the exposure of BA99 was 2- to 3-fold lower than for nanosuspensions at both pHs. Moreover, the blood concentrations of BA99 administered as microsuspension were also 2- to 3-fold lower compared with untreated (no AZD0865) individuals receiving both nanoparticles and microparticles of BA99. Obviously, for neutral compounds, with similar physicochemical properties as the present compound, size reduction will be crucial for increased plasma exposure. For basic compounds, with similar physicochemical properties as the present compound, the crucial step for absorption is the dissolution and solubility in the gastric tract.     

Preparation of azithromycin nanosuspensions by reactive precipitation method

Purpose: The aim of this work was to prepare azithromycin (AZI) nanosuspensions to increase the solubility and dissolution rate.

Method: AZI nanosuspensions were prepared by the combination of reactive precipitation and freeze-drying in presence of biocompatible stabilizer. Formulation and process variables affecting the characteristics of nanosuspensions were optimized. Various tests were carried out to study the physicochemical characteristics of AZI nanosuspensions.

Results: The nanosuspensions were parenterally acceptable and autoclavable, because soybean lecithin was the stabilizer of choice and no organic solvents were used during the preparation. The mean particle size and zeta potential of the AZI nanosuspensions were about 200?nm (±20?nm) and ?36.7 mV (±7.6 mV), respectively. Solid nanoparticles were obtained by lyophilization of the nanosuspensions and nanosuspensions rapidly reconstituted when the nanoparticles were dispersed in water. X-ray diffraction and differential scanning calorimetry analysis showed that the crystal state of nanoparticles was amorphous. Solubility and in vitro release studies indicated that the saturated solubility and dissolution rate increased obviously in comparison of raw AZI. The nanoparticles were physically stable over a period of 5 months as demonstrated by unchanged crystallinity and stable particle size when stored at room temperature and protected from humidity.

Conclusion: The results suggested that reactive precipitation is an effective way to prepare AZI nanosuspensions with increased solubility and dissolution rate.     

Preparation of fenofibrate nanosuspension and study of its pharmacokinetic behavior in rats

Background: In this study, nanosuspension was prepared to improve the dissolution rate and bioavailability of lipophilic fenofibrate. Method: Melt emulsification method combined with high-pressure homogenization was adapted, and mixture of poloxamer188 and PVP K30 were selected as surfactants. This method consumed less energy and was more efficient than traditional homogenization of drug solid particles suspension directly. Results: The dissolution rate of fenofibrate nanosuspension was increased obviously, and the product was evaluated by pharmacokinetic characteristic in rats. The AUC_{0–36 h} and C_max of nanosuspensions were increased when compared with the reference formulations. No significant differences were found between the two nanosuspensions A and B, of which the mean particle sizes were 356 and 194 nm, respectively. Therefore, nanosuspensions may be a suitable delivery system to improve the bioavailability of those drugs with poor water solubility.     

Formulation and characterisation of nanosuspensions of BCS class II and IV drugs by combinative method

Drug nanocrystals are known to increase the solubility of Biopharmaceutics Classification System (BCS) class II and IV drugs. SmartCrystals are the second generation nanocrystals with particle size of less than 100 nm and increased the stability and solubility of drug and drug product. The combinative methods adopted for the preparation of SmartCrystals are reported to shorten the processing time to reduce the particle size of the drug. This study was carried out with the aim to prepare nanosuspensions of aprepitant and ibuprofen using two pretreatment methods, precipitation and ball milling in a combination of high-pressure homogenisation (HPH). Ball milling and precipitation resulted in nanosuspensions having a particle size less than 1 µ, which were subjected to high HPH. HPH further led to a reduction in the particle size. However, the precipitation method failed to reduce the size of ibuprofen particles to 1 µ.     

Preparation of azithromycin nanosuspensions by high pressure homogenization and its physicochemical characteristics studies

The azalide azithromycin was proved to be clinically effective against Gram-positive and Gram-negative bacteria. But the low bioavailability caused by its poor solubility and gastrointestinal response limited its application in clinic. With the purpose of increasing its saturation solubility and dissolution velocity, azithromycin was produced as nanosuspensions by high pressure homogenization. Nanosuspensions could increase the drug-loading and reduce the administration dosage, thus the gastrointestinal response could be minimized. In order to enhance the stability of the nanosuspensions, we got the freeze-dried powder by lyophilization. After dispersed in distilled water, the nanoparticles had a bulk population of about 400 nm and a spherical figure (watched by transmission electron microscopy). The analysis of differential scanning calorimetry and powder X-ray diffraction demonstrated that the crystal state of azithromycin had changed. In vitro release studies showed that the dissolution rate of nanosuspension, compared with micronized powder, had been obviously increased.     

Preparation,physical characterization and pharmacokinetic study of paclitaxel nanocrystals

Paclitaxel (PTX) is a natural broad-spectrum anticancer drug with poor aqueous solubility. PTX nanocrystals were formulated to improve the water solubility, and PTX nanosuspensions were prepared using anti-solvent precipitation, and then organic solvent and surfactants were removed by filtering through a vacuum system. The physical characterization of PTX nanocrystals were measured by transmission electron microscope, X-ray diffraction and differential scanning calorimetry. In addition, saturation solubility, in vitro release, stability and pharmacokinetic characteristics were examined. The average particle size of PTX nanocrystals was ～200?nm, and they had a stable potential and a uniform distribution. Paclitaxel nanocrystals can effectively improve drug solubility and in vitro release. PTX pharmacokinetic and tissue distribution studies were compared after intravenous administration of nanocrystals versus a commercial injection formulation. PTX nanocrystals were rapidly distributed with a longer elimination phase. Moreover, tissue distribution indicated that PTX nanocrystals are mainly absorbed by the liver and spleen and may offer reduced renal and cardiovascular toxicity which may reduce side effects.     

In vitro and in vivo evaluation of cyclodextrin-based nanosponges for enhancing oral bioavailability of atorvastatin calcium

The aim of this study was to explore the feasibility of complexing the poorly water-soluble drug atorvastatin calcium (AC) with β-cyclodextrin (β-CD) based nanosponges (NS), which offer advantages of improving dissolution rate and eventually oral bioavailability. Blank NS were fabricated at first by reacting β-CD with the cross-linker carbonyldiimidazole at different molar ratios (1:2, 1:4, and 1:8), then NS of highest solubilization extent for AC were complexed with AC. AC loaded NS (AC-NS) were characterized for various physicochemical properties. Pharmacokinetic, pharmacodynamics and histological finding of AC-NS were performed in rats. The prepared AC-NS showed particles size ranged from 408.7?±?12.9 to 423?±?15.9?nm while zeta potential values varied from ?21.7?±?0.90 to ?22.7?±?0.85?mV. The loading capacity varied from 17.9?±?1.21 to 34.1?±?1.16%. DSC, FT–IR, and PXRD studies confirmed the complexation of AC with NS and amorphous state of the drug in the complex. AC-NS displayed a biphasic release pattern with increase in the dissolution rate of AC as compared to plain AC. Oral administration of AC-NS (1:4 w/w, drug: NS) to rats led to 2.13-folds increase in the bioavailability as compared to AC suspension. Pharmacodynamics studies in rats with fatty liver revealed significant reduction (p?in vivo performance of AC.     

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.     

Preparation of All-Trans Retinoic Acid Nanosuspensions Using a Modified Precipitation Method

ABSTRACT

All-Trans Retinoic Acid (ATRA) nanosuspensions were prepared with a modified precipitation method. The ATRA solution in acetone was injected into pure water by an air compressor under the action of ultrasonication. Photon correlation spectroscopy results showed that the mean particle size of ATRA nanoparticles in nanosuspensions reduced from 337 nm to 155 nm as the injection velocity increased and the polydispersity index was 0.45–0.50. The morphology of ATRA nanoparticles varied with the different concentration of ATRA solution in acetone. ATRA nanoparticles showed an amorphous state and stable in 6 months. It could be concluded that this modified precipitation method could produce stable and controllable ATRA nanosuspension to a certain extent, thus benefit for higher saturation solubility.     

Improved biopharmaceutical properties of carvedilol employing α-tocopheryl polyethylene glycol 1000 succinate-based self-emulsifying drug delivery system

The main objective of this study was to develop a self-emulsifying drug delivery system (SEDDS) of carvedilol (CAR) with improved oral absorption and hepatoprotective properties. SEDDS-CAR was prepared based on d-α-tocopheryl polyethylene glycol 1000 succinate (TPGS) and physicochemically characterized. Pharmacokinetic behaviors after the oral administration of CAR samples in rats were evaluated to clarify the possible enhancement of the oral absorption of CAR. The hepatoprotective effects of orally dosed CAR samples were assessed in a rat model of acute hepatic injury induced by carbon tetrachloride (CCl₄). SEDDS-CAR showed the immediate formation of fine micelles with a mean droplet size of 84?nm when introduced in aqueous media. SEDDS-CAR improved the dissolution behavior of CAR in distilled water as evidenced by at least five-fold higher solubility than the equilibrium solubility of CAR. After the single oral administration of SEDDS-CAR (10?mg-CAR/kg) in rats, enhanced CAR exposure was observed with an increase of AUC_0–∞ showing a 2.5-fold increase compared with crystalline CAR. In CCl₄-treated rats, orally dosed SEDDS-CAR (10?mg-CAR/kg, p.o.) led to 91.8 and 91.2% reductions of ALT and AST, respectively; however, crystalline CAR was found to be less effective. From these findings, SEDDS-CAR might be an efficacious oral dosage option for enhancing the hepatoprotective potential of CAR.     

Formulation and optimization of a novel oral fast dissolving film containing drug nanoparticles by Box–Behnken design–response surface methodology

Objective: The purpose of this study was to design and optimize a novel drug nanoparticles-loaded oral fast dissolving film (NP-OFDF) using Box–Behnken design–response surface methodology.

Methods: Drug nanosuspensions produced from high pressure homogenization were transformed into oral fast dissolving film containing drug nanoparticles by casting methods. Herpetrione (HPE), a novel and potent antiviral agent with poor water solubility that was extracted from Herpetospermum caudigerum, was studied as the model drug. The formulations of oral fast dissolving film containing HPE nanoparticles (HPE-NP-OFDF) were optimized by employing Box-Behnken design–response surface methodology and then systematically characterized.

Results: The optimized HPE-NP-OFDF was disintegrated in water within 20?s with reconstituted nanosuspensions particle size of 299.31?nm. Scanning electron microscopy (SEM) images showed that well-dispersed HPE nanoparticles with slight adhesion to each other were exposed on the surface of film or embedded in film. The X-ray diffractogram (XRD) analysis suggested that HPE in the HPE-NP-OFDF was in the amorphous state. In-vitro release study, approximate 77.23% of HPE was released from the HPE-NP-OFDF within 5?min, which was more than eight times compared with that of HPE raw materials (9.57%).

Conclusion: The optimized HPE-NP-OFDF exhibits much faster drug release rates compared to HPE raw material, which indicated that this novel NP-OFDF may provide a potential opportunity for oral delivery of drugs with poor water solubility.     

Preparation of All-Trans Retinoic Acid nanosuspensions using a modified precipitation method

All-Trans Retinoic Acid (ATRA) nanosuspensions were prepared with a modified precipitation method. The ATRA solution in acetone was injected into pure water by an air compressor under the action of ultrasonication. Photon correlation spectroscopy results showed that the mean particle size of ATRA nanoparticles in nanosuspensions reduced from 337 nm to 155 nm as the injection velocity increased and the polydispersity index was 0.45-0.50. The morphology of ATRA nanoparticles varied with the different concentration of ATRA solution in acetone. ATRA nanoparticles showed an amorphous state and stable in 6 months. It could be concluded that this modified precipitation method could produce stable and controllable ATRA nanosuspension to a certain extent, thus benefit for higher saturation solubility.     

Solidification of hesperidin nanosuspension by spray drying optimized by design of experiment (DoE)

Objective: To accelerate the determination of optimal spray drying parameters, a “Design of Experiment” (DoE) software was applied to produce well redispersible hesperidin nanocrystals.

Significance: For final solid dosage forms, aqueous liquid nanosuspensions need to be solidified, whereas spray drying is a large-scale cost-effective industrial process.

Methods: A nanosuspension with 18% (w/w) of hesperidin stabilized by 1% (w/w) of poloxamer 188 was produced by wet bead milling. The sizes of original and redispersed spray-dried nanosuspensions were determined by laser diffractometry (LD) and photon correlation spectroscopy (PCS) and used as effect parameters. In addition, light microscopy was performed to judge the redispersion quality.

Results: After a two-step design of MODDE 9, screening model and response surface model (RSM), the inlet temperature of spray dryer and the concentration of protectant (polyvinylpyrrolidone, PVP K25) were identified as the most important factors affecting the redispersion of nanocrystals. As predicted in the RSM modeling, when 5% (w/w) of PVP K25 was added in an 18% (w/w) of hesperidin nanosuspension, subsequently spray-dried at an inlet temperature of 100?°C, well redispersed solid nanocrystals with an average particle size of 276?nm were obtained. By the use of PVP K25, the saturation solubility of the redispersed nanocrystals in water was improved to 86.81?µg/ml, about 2.5-fold of the original nanosuspension. In addition, the dissolution velocity was accelerated.

Conclusions: This was attributed to the additional effects of steric stabilization on the nanocrystals and solubilization by the PVP polymer from spray drying.     

Simultaneous quantification of polymeric and surface active stabilizers of nanosuspensions by using near-infrared spectroscopy

Nanosuspension technology is an attractive approach for the formulation and solubility enhancement of poorly water-soluble drug compounds. The technology requires adequate excipients for stabilizing the suspensions during nanogrinding and storage. This study aimed at establishing a near-infrared (NIR) method for assaying simultaneously the two nanoparticle stabilizers, sodium dodecyl sulphate (SDS) and hydroxypropylcellulose (HPC), in miconazole nanosuspensions. Second derivative of NIR signals was used to establish calibration curves in concentration ranges of interest of SDS (0.03–0.3%) and HPC (0.75–7.5%). The suitability and applicability of the NIR method was verified by evaluating the linearity, accuracy, precision, and specificity of the obtained data. The method was then used to quantify indirectly the amount of SDS and HPC adsorbed onto miconazole nanoparticles. Within the concentration range of interest, SDS adsorption increased up to 122 µg/m² (4.2?×?10^?7 mol/m²) with increasing SDS concentration, and HPC adsorption was in the range of 800–1000 µg/m² (21–27?×?10^?7 mol/m²) for nanosuspensions containing nominally 5% HPC and 12.5% or 20% miconazole. Interestingly, some of the adsorbed HPC was displaced upon increase of SDS concentration and adsorption. The data were also confirmed by surface tension measurements of aqueous solutions of SDS and HPC and nanosuspension supernatants. The availability of a fast and nondestructive method for quantifying simultaneously the adsorption of two stabilizers onto nanoground particles may not only speed up nanosuspension development, but also provide insight into the mechanisms of nanoparticle stabilization regarding competitive adsorption and electrostatic versus steric stabilization.     

Evaluation on the use of confined liquid impinging jets for the synthesis of nanodrug particles

Most pharmaceutical compounds can benefit from being produced with a small particle size to enhance processing or therapeutic performance. Confined liquid impinging jets (CLIJ) were employed in this study to evaluate the feasibility and limitations in the production of nanodrugs (i.e., particle size in the nanorange). Four drugs from different pharmaceutical classes and water solubilities—salbutamol sulfate, mannitol, ibuprofen, and cyclosporine—were examined. Particles of salbutamol sulfate and cyclosporine with diameters of approximately 300 nm were successfully achieved. The use of CLIJ thus shows potential in the production of nanopharmaceuticals for certain compounds.     

Sugars as solid dispersion carrier to improve solubility and dissolution of the BCS class II drug: clotrimazole

Solid dispersion of poorly soluble BCS class II drug, clotrimazole, was prepared with the aim of enhancing its dissolution profile. Solid dispersions were prepared using various sugars as carriers at different weight ratio to drug-like d-mannitol, d-fructose, d-dextrose and d-maltose by fusion method. The solubility of plain clotrimazole in different percent of sugar solutions was measured. Also, its solubility in solid dispersion and their physical mixture were assessed. The dissolution of all the prepared SD tablets, direct compressed clotrimazole tablet and plain drug were tested using the U.S. Pharmacopeia convention (USP) apparatus II. The dissolution profiles were characterized by parameters like area under curve (AUC), mean residence time (MRT), mean dissolution time (MDT) and percent dissolution efficiency (% DE). The release kinetics study was performed using DD Solver TM software. The selected solid dispersions (SDs) were evaluated for antifungal activity. A 100% solution of mannitol showed 806-fold increases in solubility as compared with plain clotrimazole in water. It was observed that the dissolution profile of clotrimazole was improved by mannitol SD at drug to sugar ration of 1:3. The percent DE value for mannitol SD tablet was found to be 77.3516% as against plain drug and directly compressed tablet of clotrimazole at 50.9439% and 31.33%, respectively. Also the antifungal activity indicated by inhibition zone was found to be 54?mm indicating enhance activity against Candida albicans as compared with plain CTZ at 6.6?mm. Thus, it can be concluded that the sugar alcohol, that is, mannitol is a more promising hydrophilic carrier for solid dispersion preparation to improve the solubility and dissolution of poorly soluble drugs.     

Simultaneous quantification of polymeric and surface active stabilizers of nanosuspensions by using near-infrared spectroscopy

Nanosuspension technology is an attractive approach for the formulation and solubility enhancement of poorly water-soluble drug compounds. The technology requires adequate excipients for stabilizing the suspensions during nanogrinding and storage. This study aimed at establishing a near-infrared (NIR) method for assaying simultaneously the two nanoparticle stabilizers, sodium dodecyl sulphate (SDS) and hydroxypropylcellulose (HPC), in miconazole nanosuspensions. Second derivative of NIR signals was used to establish calibration curves in concentration ranges of interest of SDS (0.03-0.3%) and HPC (0.75-7.5%). The suitability and applicability of the NIR method was verified by evaluating the linearity, accuracy, precision, and specificity of the obtained data. The method was then used to quantify indirectly the amount of SDS and HPC adsorbed onto miconazole nanoparticles. Within the concentration range of interest, SDS adsorption increased up to 122 μg/m(2) (4.2?×?10(-7) mol/m(2)) with increasing SDS concentration, and HPC adsorption was in the range of 800-1000 μg/m(2) (21-27?×?10(-7) mol/m(2)) for nanosuspensions containing nominally 5% HPC and 12.5% or 20% miconazole. Interestingly, some of the adsorbed HPC was displaced upon increase of SDS concentration and adsorption. The data were also confirmed by surface tension measurements of aqueous solutions of SDS and HPC and nanosuspension supernatants. The availability of a fast and nondestructive method for quantifying simultaneously the adsorption of two stabilizers onto nanoground particles may not only speed up nanosuspension development, but also provide insight into the mechanisms of nanoparticle stabilization regarding competitive adsorption and electrostatic versus steric stabilization.     

Preparation of drug nanocrystals embedded in mannitol microcrystals via liquid antisolvent precipitation followed by immediate (on-line) spray drying

The aim of this study is to investigate the feasibility of producing pharmaceutical nanoformulations for enhanced oral or pulmonary delivery of poorly water-soluble drugs via liquid antisolvent precipitation followed by immediate (on-line) spray drying. A poorly water-soluble corticosteroid, budesonide, was chosen as the model drug. Budesonide nanoparticles were prepared through liquid antisolvent precipitation, and then processed into a powdered nanoformulation which consists of budesonide nanoparticles embedded in mannitol microcrystals by immediate (on-line) spray drying. The size of the freshly precipitated and the reconstituted budesonide particles was analyzed by dynamic light scattering (DLS). The spray-dried nanoformulation, together with budesonide and mannitol raw materials, their physical mixture and the spray-dried mannitol, were characterized by field emission scanning electron microscopy (FESEM), differential scanning calorimetry (DSC) and powder X-ray diffraction (PXRD). In vitro dissolution test and aerosol deposition study were conducted on the spray-dried nanoformulation and the physical mixture of budesonide and mannitol raw materials. It was found that the spray-dried nanoformulation, consisting of mannitol microcrystals comprising budesonide nanocrystals with z-average mean size of 520?±?11.4?nm, exhibited enhanced drug dissolution rate and higher fine particle fraction (FPF). The results of this study indicated the potential of the combined process of liquid antisolvent precipitation followed by immediate (on-line) spray drying to be used as a direct and continuous formulation process to produce powdered nanoformulations to achieve enhanced oral or pulmonary delivery of poorly water-soluble drugs.     

Preparation,characterization, stability and in vitro-in vivo evaluation of pellet-layered Simvastatin nanosuspensions

The objective of the present study was to develop stable pellets-layered Simvastatin (SIM) nanosuspensions with improved dissolution and bioavailability. The nanosuspensions were prepared with 7% HPMC, antioxidant 0.03% butylated hydroxyanisole and 0.2% citric acid (m/v) by low temperature grinding. After that, SDS with SIM was in a ratio of 1:5 (m/m), was evenly dispersed in the nanosuspensions. Then, they were layered on the surface of sugar pellets. The mean particle size of the SIM nanosuspensions was 0.74 µm, and 80.6% of the particles was below 1 µm in size. The pellets could re-disperse into nanoparticle status in the dissolution medium. In 900?mL pH 7.0 phosphate solutions, the dissolution of the layered pellets was better than that of commercial tablets. Also, nearly 100% of the drug dissolved from the pellets within 5?min under sink conditions. During the stability studies, SIM pellets exhibited good physical and chemical stability. The relative bioavailability of SIM and Simvastatin β-hydroxy acid (SIMA) for nanosuspensions layered pellets compared with commercial tablets was 117% and 173%, respectively. The bioavailability of SIMA was improved significantly (p < 0.05), confirming the improvement of bioavailability. Thus, the present study demonstrates that the pellet-layered SIM nanosuspensions improved both the dissolution and bioavailability of SIM.