Targeted Cancer Therapy With Novel High Drug-Loading Nanocrystals

A novel nanocrystal formulation of hydrophobic drugs has been developed for cancer therapy. The new method, called a three-phase nanoparticle engineering technology (3PNET), includes three phases: phase 1, amorphous precipitate; phase 2, hydrated amorphous aggregate; and phase 3, stabilized nanocrystal. The 3PNET has been applied to two anticancer drugs, paclitaxel (PTX) and camptothecin (CPT), using Pluronic F127 (F127) polymer as a single excipient. The nanocrystals encapsulated over 99% of the drug with a high ratio of drug to excipient. The nanocrystal formulation of PTX did not induce hemolysis at pharmacologically relevant concentrations. Antitumor activity in two tumor models, human lung cancer and murine breast cancer, demonstrated that intravenously injected nanocrystals significantly inhibited the tumor growth. The nanocrystals also showed significant therapeutic effects via oral administration. In addition, the nanocrystals could be further modified for targeted delivery of PTX by conjugating a folate ligand to F127. The new nanomedicine formulations show clear potential for clinical development because of the excellent antitumor activity, low toxicity, and the ease of scale-up manufacture. The formulation method may apply to other hydrophobic drugs.     

Development and characterization of micellar systems for application as insect repellents

N,N-diethyl-meta-toluamide (DEET) is a widely used insect repellent due to its high efficacy. In this work, micellar systems based on poly(ethylene oxide)–poly(propylene oxide)–poly(ethylene oxide) triblock copolymer were developed and studied for the purpose of controlling the release and cutaneous permeation of DEET, using concentrated solutions of the copolymer Pluronic F127 to form thermoreversible gels. The formulations presented thermoreversible gelation above 5 °C and altered rheological behavior at 15 and 25 °C. The presence of the drug drastically changed the sol–gel transition temperatures. The micrographs suggest that DEET induced the formation of anisotropic structures, and Maltese Crosses were observed. The formulation containing 10 wt% DEET and 15 wt% Pluronic F127 presented sustained drug release for up to 7 h. DEET release profile followed the Higuchi kinetics model. There was a reduction of approximately 35% in the amount of DEET absorbed through the skin after 6 h. About 62% of DEET from the formulation consisting of Pluronic F127 and DEET remain retained on the skin. The anisotropic structure may constitute a barrier to diffusion and thereby controlling the drug release effectively. These tests suggest that the tested samples exhibit safety profile greater than some commercially available products.     

Preparation of sodium cholate-based micelles through non-covalent ıbonding interaction and application as oral delivery systems for paclitaxel

In present study, two types of micelles based on sodium cholate (NaC) were prepared through non-covalent bonding interaction and the potential of micelles as oral drug delivery systems for paclitaxel (PTX) was evaluated. Pluronic–chitosan (F127–CS) and Pluronic–poly (acrylic acid) (F127–PAA) copolymers were synthesized. Electrostatic interaction and hydrogen bond were used to prepare F127–CS/NaC micelles and F127–PAA/NaC micelles, respectively. The physicochemical characteristics of micelles were determined. An average diameter of 67.5?nm and unimodal pattern of size distribution were observed for F127–CS/NaC micelles. While for F127–PAA/NaC micelles, an average diameter of 85.89?nm and non-unimodal pattern of size distribution were observed. The results revealed that F127–CS/NaC micelles were more integrated than F127–PAA/NaC micelles. Further experiments showed that the F127–CS/NaC micelles had a higher drug-loading content of 12.8% and a lower critical micelle concentration (CMC) of 2.5?×?10^?3?mol/L compared with F127–PAA/NaC micelles. In vitro cytotoxicity analysis demonstrated that the PTX-loaded F127–CS/NaC micelles were of great efficiency in inhibiting the growth of drug-resistant breast cancer MCF-7 cells (MCF-7/Adr). The intragastric administration of the PTX-loaded F127–CS/NaC micelles in rats provided a 4.33-fold higher absolute bioavailability compared to commercial Taxol®, indicating an efficient oral absorption of PTX delivered by micelles. These findings signify that F127–CS/NaC micelle may be a promising carrier for the delivery of PTX.     

Syringeable Pluronic-α-cyclodextrin supramolecular gels for sustained delivery of vancomycin

The ability of Pluronic® F127 to form supramolecular gels in the presence of αCD has been explored as a way to design syringeable gel formulations able to sustain drug release while using the lowest proportion of both components. The effects of αCD concentration range (0-9.7% w/v) in copolymer (6.5%, 13% and 20%) gel features were evaluated at 4, 20 and 37 °C. An effective complexation of Pluronic and αCD was evidenced as a change in the surface pressure of the π-A isotherm of Pluronic on a subphase of CD solution and the apparition of new peaks in the X-ray spectra. Once the Pluronic and αCD solutions were mixed, the systems became progressively turbid solutions or white gels. The greater the αCD concentration was, the faster the gel formation. The supramolecular hydrogels were thixotropic and those containing 5% or more αCD had G′ values above G″ at room temperature, but they were still easily syringeable. The values of both moduli increased as temperature raised; the effect being more evident for 13% and 20% w/v copolymer. The gels prepared with low proportions of αCD exhibited phase separation in few days, particularly when stored at 4 or 37 °C. By contrast, those prepared with 6.5% copolymer were stable for at least two months when stored at 20 °C. The gels were able to sustain vancomycin release for several days; the higher the αCD proportion, the slower the release was. Furthermore, the drug-loaded gels showed activity against Staphylococcus aureus. The results obtained highlight the role of the αCD concentration on the tuning of the rheological features and drug release profiles from Pluronic gels.     

Enhancement on oral absorption of paclitaxel by multifunctional pluronic micelles

The aim of the present study is to synthesize Pluronic F127-polyethylenimine-folate (PF127-PEI-FA) copolymer, construct a mixed micelle system with PF127-PEI-FA copolymer and Pluronic P123 (PP123) and to evaluate the potential of these mixed micelles as an oral drug delivery system for paclitaxel (PTX). The results of intestinal absorption revealed that the PTX-loaded micelles displayed superior permeability across intestinal barrier than free drug and PF127-PEI-FA/PP123 mixed micelles exhibited the strongest permeability across intestinal barrier. These results were also proved by the studies on cytotoxicity and cell uptake tests. The mechanism was demonstrated in connection with inhibition of the efflux mediated by intestinal P-glycoprotein (P-gp) and enhancement of the electrostatic interaction of positive micelles with the negative intestinal epithelial cells, thereby promoting the permeation across the intestinal wall. The presence of verapamil and Pluronic both improved the intestinal absorption of PTX, which further certified the effect of Pluronic on P-gp inhibition. Pharmacokinetic study demonstrated that the area under the plasma concentration-time curve (AUC_{0→36 h}) of PTX-loaded micelles was three times greater than the PTX solution (dissolved in a 50/50 (vol/vol) mixture of Cremophore EL/dehydrated ethanol) (p < 0.05). In general PF127-PEI-FA/PP123 mixed micelles were proved to be potential oral drug delivery system for PTX.     

Controlling lipolysis through steric surfactants: new insights on the controlled degradation of submicron emulsions after oral and intravenous administration

In this work we have investigated how steric surfactants influence the metabolic degradation of emulsions (lipolysis). To do so, we have prepared submicron emulsions stabilized with Pluronic F68, Pluronic F127, Myrj 52 or Myrj 59, four non-ionic surfactants with key differences on their structure. Submicron emulsions have been prepared also with mixtures of these surfactants with different proportions between them. Then, in vitro methods have been applied to analyze the lipolysis of these emulsions, both under duodenal and intravenous conditions, to simulate lipolysis after oral and intravenous administration. Our results show that the properties of the surfactant influence dramatically the lipolysis rates observed both under duodenal and intravenous conditions, e.g., intravenous lipolysis was completely blocked when Pluronic F127 was used, while it was almost complete within 6 h when using Myrj 52. The reason for this seems to be the steric hindrance that the surfactant produces around the droplet and at the interface. As a result, we can modify the lipolysis patterns by changing some characteristics of the surfactant, or by varying the proportion between two surfactants in a mixture. These findings may be applied in the development of novel strategies to rationally design submicron emulsions as lipophilic drug carriers.     

Evaluation of non-isothermal methods in stability studies of human insulin pharmaceutical preparations

The purpose of this research was to study the thermal stability of a human insulin pharmaceutical preparation using non-isothermal conditions and comparison with classical isothermal experiments. The isothermal studies were performed in the temperature range 20–60 °C, whereas non-isothermal stability studies were performed using a linear increasing temperature program, heating rate 0.25 °C per hour and temperature interval 30–70 °C.     

Stable phosphatidylcholine-bile salt mixed micelles enhance oral absorption of paclitaxel: preparation and mechanism in rats

Abstract

The aim of this study is to prepare a stable phosphatidylcholine/bile salt micelles with Pluronic F127-polyethylenimine conjugates (F127-PEI), d-α-tocopheryl polyethylene glycol 1000 succinate (TPGS), soybean phosphatidylcholine (SPC) and sodium cholate (NaC) and to elucidate the effects and possible mechanism of micelle components on the intestinal absorption of paclitaxel (PTX) in rats. The results of intestinal absorption revealed that the PTX in SPC/NaC micelles displayed superior permeability across intestinal barrier than free drug and PTX in TPGS/SPC/NaC and F127-PEI/TPGS/SPC/NaC mixed micelles exhibited the strongest permeability across intestinal barrier. These results were also proved by the studies on cell uptake tests. The mechanism was demonstrated in connection with inhibition of the efflux mediated by intestinal P-gp and enhancement of the drug transportation across the unstirred water layer to the endothelial lining, thereby promoting the permeation across the intestinal wall. Pharmacokinetic study demonstrated that the area under the plasma concentration–time curve (AUC_0→∞) of paclitaxel in F127-PEI/TPGS/SPC/NaC micelles was much greater than that in TPGS/SPC/NaC micelles. This phenomenon deviated from the results of uptake studies by cells and permeability experiments through rat intestine and revealed that the micelle stability had a great effect on intestinal absorption of paclitaxel.     

Surfactant effects on carbon nanotube interactions with human keratinocytes

Interactions of multiwalled carbon nanotubes (MWCNTs) with human epidermal keratinocytes (HEKs) were studied with respect to the effect of surfactant on dispersion of MWCNT aggregates and cytotoxicity. Our earlier studies had shown that the unmodified MWCNTs were localized within the cytoplasmic vacuoles of HEKs and elicited an inflammatory response. However, MWCNTs in solution tend to aggregate and, therefore, cells are exposed to large MWCNT aggregates. The purpose of this study was to find a surfactant that prevents the formation of large aggregates of MWCNTs without being toxic to the HEKs. HEKs were exposed to serial dilutions (10% to 0.1%) of L61, L92, and F127 Pluronic and 20 or 60 Tween for 24 hours. HEK viability, proportional to surfactant concentration, ranged from 27.1% to 98.5% with Pluronic F127; viability with the other surfactants was less than 10%. Surfactants dispersed and reduced MWCNT aggregation in medium. MWCNTs at 0.4 mg/mL in 5% or 1% Pluronic F127 were incubated with HEKs and assayed for interleukin 8 (IL-8). MWCNTs were cytotoxic to HEKs independent of surfactant exposure. In contrast, MWCNT-induced IL-8 release was reduced when exposed to 1% or 5% Pluronic F127 (P < .05). However, both MWCNTs and surfactant, alone or in combination, increased IL-8 release compared with control exposures at 12 and 24 hours. These results suggest that the surfactant-MWCNT interaction is more complex than simple dispersion alone and should be investigated to determine the mode of interaction.     

Assessing the physical–chemical properties and stability of dapivirine-loaded polymeric nanoparticles

Nanocarriers may provide interesting delivery platforms for microbicide drugs and their characterization should be addressed early in development. Differently surface-engineered dapivirine-loaded, poly(epsilon-caprolactone) (PCL)-based nanoparticles (NPs) were obtained by nanoprecipitation using polyethylene oxide (PEO), sodium lauryl sulfate (SLS), or cetyltrimethylammonium bromide (CTAB) as surface modifiers. Physical–chemical properties of NP aqueous dispersions were evaluated upon storage at −20–40 °C for one year. NPs presented 170–200 nm in diameter, roundish-shape, low polydispersity index (≤0.18), and high drug association efficiency (≥97%) and loading (≥12.7%). NPs differed in zeta potential, depending on surface modifier (PEO: −27.9 mV; SLS: −54.7 mV; CTAB: +42.4 mV). No interactions among formulation components were detected by differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy (FTIR), except for SLS–PCL NPs. Colloidal properties of NPs were lost at −20 °C storage. Negatively charged NPs were stable up to one year at 5–40 °C; as for CTAB–PCL NPs, particle aggregation was observed from 30 to 90 days of storage depending on temperature. Colloidal instability affected the in vitro drug release of CTAB–PCL NPs after 360 days. In any case, no degradation of dapivirine was apparent. Overall, PEO–PCL and SLS–PCL NPs presented suitable properties as nanocarriers for dapivirine. Conversely, CTAB–PCL NPs require additional strategies in order to increase stability.     

Lutein nanocrystals as antioxidant formulation for oral and dermal delivery

Lutein is a well known antioxidant and anti-free radical used in cosmetic, nutraceutical industry with potential application in pharmaceutics as supportive antioxidant in treatments. As lipophilic molecule it is poorly soluble in water and has a low bioavailability. Lutein nanosuspension was prepared to enhance dissolution velocity, saturation solubility (C_s), which are major factors determining oral bioavailability and penetration into the skin. High pressure homogenization (HPH) was used to prepare lutein nanosuspension. Particle size was determined by photon correlation spectroscopy (PCS) and laser diffractometry (LD). The lowest PCS diameter obtained was about 429 nm, the LD diameter 90% of 1.2 μm. The zeta potential was about −40 mV in water and −17 mV in the original dispersion medium. The 3 month storage study at different temperatures (4 °C, 25 °C, 40 °C) confirmed physical stability despite the low zeta potential of −17 mV in original surfactant solution. A pronounced increase in saturation solubility by 26.3 fold was obtained for lutein nanocrystals compared to coarse powder. The lutein nanosuspension was converted into pellets and filled into hard gelatin capsules for nutraceutical use, showed a superior in vitro release (factor of 3-4). Lyophilized nanosuspension was prepared for subsequent incorporation into creams and gels. The lyophilized nanosuspension was very well re-dispersible (435 nm). Using cellulose nitrate membranes as in vitro model, permeation through this barrier was 14× higher for lutein nanocrystals compared to coarse powder. However, pig ear skin did not allow lutein to permeate but supported localization of the lutein in the skin where it should act anti-oxidatively.     

Development of a Nanocrystalline Paclitaxel Formulation for Hipec Treatment

Purpose

To develop a nanocrystalline paclitaxel formulation with a high paclitaxel-to-stabilizer ratio which can be used for hyperthermic intraperitoneal chemotherapy (HIPEC).

Methods

Paclitaxel (PTX) nanocrystals were prepared via wet milling using Pluronic F127^? as stabilizer. The suitability of paclitaxel nanosuspensions for HIPEC treatment was evaluated by analyzing the cytotoxicity of both stabilizer and formulation, and by determining the maximum tolerated dose (MTD) and bioavailability. The effect on tumor growth was evaluated by magnetic resonance imaging (MRI) at day 7 and 14 after HIPEC treatment in rats with peritoneal carcinomatosis of ovarian origin.

Results

Monodisperse nanosuspensions (±400?nm) were developed using Pluronic F127^? as single additive. The cytotoxicity and MTD of this nanocrystalline formulation was similar compared to Taxol^?, while its bioavailability was higher. MRI data after HIPEC treatment with a PTX nanocrystalline suspension showed a significant reduction of tumor volume compared to the non-treated group. Although no significant differences on tumor volume were observed between Taxol^? and the nanosuspension, the rats treated with the nanosuspension recovered faster following the HIPEC procedure.

Conclusion

Nanosuspensions with a high paclitaxel-to-stabilizer ratio are of interest for the treatment of peritoneal carcinomatosis of ovarian origin via HIPEC.     

Biodegradable multiblock poly(N-2-hydroxypropyl)methacrylamide gemcitabine and paclitaxel conjugates for ovarian cancer cell combination treatment

The synthesis, characterization, and in vitro evaluation of a combination delivery of multiblock poly(N-2-hydroxypropyl)methacrylamide (HPMA), gemcitabine (GEM) and paclitaxel (PTX) conjugates is described in this study. Multiblock copolymer conjugates of a large molecular weight (M_w > 200 kDa) were studied and compared to traditional, small molecular weight (M_w < 45 kDa) conjugates. Stability of the conjugates in different pH was assessed, and their cytotoxicity in combination toward A2780 human ovarian cancer cells was evaluated by combination index analysis. Treatment duration (4 and 72 h) and sequence of addition were explored. In addition, an HPMA copolymer conjugate with both GEM and PTX in the side chains was evaluated in a similar manner and compared to a physical mixture of individual conjugates. Conjugates with narrow molecular weight distribution (M_w/M_n < 1.1) were obtained via RAFT polymerization, and drug loadings of between 5.5 and 9.2 wt% were achieved. Conjugates demonstrated moderate stability with less than 65% release over 24 h at pH 7.4, and near complete drug release in the presence of the lysosomal enzyme cathepsin B in 3 h. In combination, the cytotoxic effects of a mixture of the conjugates were primarily additive. Synergistic effects were observed when A2780 human ovarian cancer cells were treated simultaneously for 4 h with multiblock conjugates (CI < 0.7). When both GEM and PTX were conjugated to the same copolymer backbone, moderate antagonism (CI 1.3–1.6) was observed. These results demonstrate that multiblock HPMA copolymer–GEM and –PTX conjugates, when delivered as a mixture of individual agents, are promising for the treatment of ovarian cancer.     

Preparation and characterization of polymeric micelles for solubilization of poorly soluble anticancer drugs.

The objective of this study is to investigate the solubilization of poorly water-soluble anticancer drugs, octaethylporphine (OEP), meso-tetraphenyl porphine (mTPP) and camptothecin (CPT), in Pluronic and polyethylene glycol-distearoylphosphatidylethanolamine (PEG-DSPE) polymeric micelles. Three different Pluronic and PEG-DSPE polymers with various chain lengths were chosen and micelle formulations were prepared by using various drug:polymer ratios. Formulations were characterized by critical micellization concentration (CMC) values of copolymers, micelle particle size and distribution, zeta potential, loading efficiency and stability. Polymers formed very stable, low CMC micelles with smaller sizes than 100 nm. It was shown that drug loading efficiency highly depends on the polymer type, drug type and their ratios. The most efficient drug loading was obtained by loading mTPP in PEG2000-DSPE and Pluronic F127 micelles. This result is attributed to phenyl groups in mTPP might lead to attraction between alkyl groups in the polymer and increase drug incorporation. PEG-DSPE formulations had higher zeta potential values indicating that they would be more stable against aggregation than Pluronic micelles. From the drug assay aspect Pluronic micelles remained more stable in 3-month long stability test. These results showed that besides their solubilizing effects, polymeric micelles could be useful as novel drug carriers for hydrophobic drugs.     

Physical Stability of Ethyl Diatrizoate Nanocrystalline Suspension in Steam Sterilization

Purpose. To study the effects of formulation variables on the physical stability of a submicron crystal (nanocrystal) suspension under steam sterilization conditions. Methods. Suspensions of ethyl diatrizoate nanocrystals were prepared by wet milling in the presence of the surfactant poloxamine 908. Particle size distribution and zeta potential were measured by photon correlation spectroscopy. Results. On heating, the mean particle size of the nanocrystal suspension remained essentially unchanged up to 110°C, the cloud point of the stabilizing surfactant, but increased significantly above that temperature. The increase in particle size was a result of particle aggregation rather than crystal growth. Adding a cloud point booster to the suspension significantly minimized the particle aggregation at high temperatures. The purity of poloxamine 908 and the tonicity agent and buffer salt used also affected the heat stability of the suspension, the latter agents apparently through altering the surfactant cloud point. Conclusions. The aggregation of the ethyl diatrizoate nanocrystalline suspension under steam sterilization conditions was a result of phase separation of the stabilizing surfactant at its cloud point. When formulated with a cloud point booster to prevent the phase-separation, the suspension maintained its physical stability under steam sterilization without any significant change in particle size distribution.     

Progress in the development of stabilization strategies for nanocrystal preparations

In recent years, nanocrystal technology has been extensively investigated. Due to the submicron particle size and unique physicochemical properties of nanocrystals, they overcome the problems of low drug solubility and poor bioavailability. Although the structures of nanocrystals are simple, the further development of these materials is hindered by their stability. Drug nanocrystals with particle sizes of 1∼1000 nm usually require the addition of stabilizers such as polymers or surfactants to enhance their stability. The stability of nanocrystal suspensions and the redispersibility of solid nanocrystal drugs are the key factors for the large-scale production of nanocrystal preparations. In this paper, the factors that affect the stability of drug nanocrystal preparations are discussed, and related methods for solving the stability problem are put forward.     

Evaluation of solubility and partition properties of ampicillin-based ionic liquids

In order to overcome the problems associated with low water solubility, and consequently low bioavailability of active pharmaceutical ingredients (APIs), herein we explore a modular ionic liquid synthetic strategy for improved APIs. Ionic liquids containing l-ampicillin as active pharmaceutical ingredient anion were prepared using the methodology developed in our previous work, using organic cations selected from substituted ammonium, phosphonium, pyridinium and methylimidazolium salts, with the intent of enhancing the solubility and bioavailability of l-ampicillin forms. In order to evaluate important properties of the synthesized API-ILs, the water solubility at 25 °C and 37 °C (body temperature) as well as octanol–water partition coefficients (K_ow's) and HDPC micelles partition at 25 °C were measured. Critical micelle concentrations (CMC's) in water at 25 °C and 37 °C of the pharmaceutical ionic liquids bearing cations with surfactant properties were also determined from ionic conductivity measurements.     

Combination of Pluronic/Vitamin E TPGS as a potential inhibitor of drug precipitation

In this study, we screened surfactants and their combinations at low concentrations as potentially potent inhibitors of drug precipitation in an aqueous medium. Nine surfactants (including Pluronic F127, Pluronic F108, and Pluronic F68) were evaluated at concentrations below their critical micelle concentrations (CMCs) using an in vitro precipitation assay. A model compound used in this study showed a sharp pH-dependent solubility profile and was much more soluble in simulated gastric fluid (SGF) (pH 1.2) than in simulated intestinal fluid (SIF) (pH 7.4). The compound was first dissolved in SGF with each surfactant, and the solutions were dispensed into the wells of a 96-well microtiter plate by a TECAN robot and diluted 10-fold with SIF. After a preset incubation time at room temperature, the solutions were filtrated through a 96-well filter plate, and the compound concentration in the filtrate was measured using an HPLC method. At concentrations below their CMCs, Pluronic F127 and Pluronic F108, but not Pluronic F68, inhibited the compound precipitation in SIF. Combinations of Pluronic F127 or Pluronic F108 with Vitamin E TPGS showed significantly stronger inhibition than the individual surfactants, indicating synergistic effects on inhibition of drug precipitation.     

Modeling the effects of storage temperature excursions on shelf life

Excursions from storage condition requirements may affect product performance and stability. The effects of temperature excursion on stability depend on the amount of time that a product is subjected to these conditions, temperature level, and activation energy. Both time at elevated temperature and the temperature level can be directly measured, while activation energy needs to be estimated from the accelerated stability tests. Coulter Clenz^® reagent degradation information is used to demonstrate the effects of temperature excursions. The stability of the product is affected by any excursion, but Coulter Clenz^® will not lose all of its stability for excursion of up to 30 days at 35 °C and 20 days at 40 °C. Temperature excursion for up to 20 days at 40 °C will reduce the stability of a product that has activation energy in the range of 26–30 kcal mol⁻¹ approximately by 5–7 months. Products with lower activation energy will have a significantly lower reduction in stability. The effects of excursions on shelf life performance are less severe when lower level of risk is implemented to establish the claimed shelf life. The proposed model can effectively predict temperature excursion if used within the scope of a product performance and its characteristics.     

Effects of particle size on the pharmacokinetics of puerarin nanocrystals and microcrystals after oral administration to rat

Puerarin, which is extracted from traditional Chinese medicine, is widely used in clinic in China and mainly used as a therapeutic agent to cardiovascular diseases. Owing to its poor water solubility and adverse drug reactions caused by cosolvents after intravenous administration, the development of oral formulation is urgently needed. Nowadays, nanocrystals technique has become a preferred way to develop oral dosage form. In this study, we used high pressure homogenization (HPH) to prepare puerarin nanocrystals and microcrystals with different sizes ranged from 525.8 nm to 1875.6 nm and investigated the influence of particle size on pharmacokinetics. The nanocrystals and microcrystals prepared were characterized using DLS, DSC, XRD and SEM, and we found that the crystalline state of puerarin was changed during the preparation process and the drug was dispersed into HPMC. In the pharmacokinetic study, we observed an increasing of C_max and AUC and a decreasing of CL/F with the decreasing of particle size. The AUC of the puerarin nanocrystals (525.8 nm) was 7.6-fold of that of raw puerarin suspension, with an absolute bioavailability of 21.44%. From the above results, we can conclude that nanocrystal technique is an efficient technology to improve the oral bioavailability of puerarin.