Curcumin was a gift sample from Indsaff Inc., Bhubaneswar, India. Curcumin nanosuspensions were stabilized by Polyvinyl alcohol (PVA, molecular weight 90,000) and sodium dodecyl sulfate. Double-distilled water was used as dispersion medium. The other chemicals were of analytical reagent grade (SRL, Mumbai, India).

The Curcumin nanosuspension (Cur-NS) was produced via high pressure homogenization in pure water using a Micron Lab 40 at room temperature, applying 20 homogenization cycles at 1500 bar (equal to 150,000 kPa and 21,756 psi) from spray dried material.

Spray-drying was employed to obtain freely flowable Curcumin nanocrystal powder. For that Curcumin nanosuspensions, having a drug concentration of 10% (w/w), were dried with a Mini Spray-dryer B-190. The mini Spray-dryer B-190 was set with regard to temperature inlet (110˚C - 100˚C), outlet (74˚C - 76˚C) and air volume (600 l/h). The spray-dried Curcumin nanocrystals were directly collected after the process.

Photon correlation spectroscopy (PCS) (Zetasizer Nano ZS) and laser diffraction (LD) (Coulter LS230) were employed to determine the particle size. PCS measurements were performed at 20˚C and each sample was analysed three times. PCS yields the intensity weighted mean diameter of the bulk population (z-average, measuring range: 3 nm - 3 μm) and the polydispersity index (PI) as measures for the width of the size distribution. The PI ranges from zero (monodisperse particles) to 0.500 (broad distribution), values above 0.5 do not allow allocation of a logarithmic normal distribution to the PI. LD was repeated three times and the results were calculated as volume size distribution using Mie theory with the optical parameters 1.593 for the real refractive index and 0.01 for the imaginary refractive index. As characterisation parameters the diameters 10%, 50%, 90% and 99% were used. For example diameter 99% means that 99% of the particles are below the given size value.

Formulations of the Curcumin capsules can be seen in Table 1. Curcumin was admixed to the capsule excipients by a tumbler (Turbula, Basel). The mixed powder was filled into hard gelatin capsule No. 2 using simple filling capsule equipment for lab scale. The final product of the capsules was collected and immediately transferred into dry plastic containers and tightly sealed.

The dissolution test of the capsules was performed using a USP XXIV rotating paddle apparatus with a Pharmatest PTW SIII (Pharma Test, Hamburg, Germany) at 37˚C and a rotating speed of 50 rpm in 900 ml of medium. Capsules were held to the bottom of the vessel using copper sinkers. Samples were analyzed for drug concentration using HPLC.

A validated sensitive and selective high-performance liquid

Table 1. The formulations of curcumin capsules.

NC = Curcumin nanocrystal, MC = Curcumin microcrystal; Mg = Magnesium stearate, AV = Avicel PH 102, Lc = Lactose, Market = Marketed capsule.

chromatography (HPLC) no change method using UV detection was used for the determination and quantification of curcumin. The HPLC system consisted of a Shimadzu LC 6A HPLC instrument equipped with a solvent delivery pump, a Rheodyne injector valve and a variable wavelength UV detector. The column used was C 18 analytical column (4.6 × 250 mm, particle size 5 µm), with mobile phase consisting of two components: A, 10 mM ammonium acetate pH 4.5; B, acetonitrile. Initial conditions were 95% A progressing to 55% A at 20 min and 5% A at 33 min. The flow rate was maintained at 1 mL/min at 45˚C ± 2˚C. The eluate was monitored at 420 nm. Retention time for curcumin was 8 min. Free curcumin is completely insoluble in water therefore the concentration of curcumin was calculated using standard curve of curcumin in ethanol. The data was recorded and calculated using Winchrome software.

The curcumin nanosuspension on a lab scale is typically produced by pre-milling (with SDS 0.2%) followed by high pressure homogenization in pure water using a continuous Micron LAB 40 at room temperature, applying 20 homogenization cycles at 1500 bar. The formulation of curcumin nanosuspension was prepared using Curcumin 10%, Polyvinyl alcohol 2% and Water 88%. Figure 2 clearly shows the difference between the ordinary suspension and the nanosuspension obtained. Nanonisation renders curcumin completely dispersible in aqueous media. Free curcumin is poorly soluble in aqueous media, and macroscopic flakes can be seen floating in the bottle. In contrast, the equivalent quantity of curcumin nanoparticles is fully dispersible in aqueous media. Figure 3 shows the particles size distribution of curcumin formulations by PCS and LD. The Cur-NS-B had LD particle size distribution of 0.1 μm (

fine stable homogeneous distribution. It showed very good physical and chemical stability over 3 and 6 months period respectively. A spray drying process was employed to obtain dried curcumin nanocrystals having good re-dispersability, saturation solubility and dissolution velocity. LD values were 0.13 μm (

Nanosizing refers to the reduction of drug particle size down to the submicron range. While reduction of particle size has been employed in pharmaceutical industry for several decades, recent advances in milling technology and our understanding of such colloidal systems have enabled the production of drug particles of 50 - 200 nm size in a reproducible manner. The sub-micron particles are stabilized with surfactants or polymers in nanosuspensions which can be further processed into standard dosage forms suitable for oral administration. These nanosuspensions offer increased dissolution rates for drug compounds and complement other technologies used to enhance the bioavailability of insoluble compounds (BCS Class II and IV), such as solubility enhancers (i.e. surfactants), liquid-filled capsules or solid dispersions of drugs in their amorphous state. Based on the NoyesWhitney principle, reduction in the particle size will increase the dissolution rate due to increased effective particle surface area. This size-dependency comes only into effect for particles of a size below approximately 1 μm (submicron particulate)—a phenomenon observed in solid dosage which leads to an increase of the dissolution rate of such fine drug particles [23,24].

On the market, no oral curcumin capsule is found in single dose form. Curcumin is normally not combined with any other drugs. CUR-500^® capsules compared in this study contain 500 mg curcumin. The formulations of curcumin capsules can be seen in Table 1. Curcumin nanocrystals were admixed to the capsule excipients in a tumbler. On a lab scale, the capsules were prepared using simple capsule filling equipment. The mixed powder was gently poured into capsule no. 2 using the capsule filling equipment. Avicel PH 102, lactose, magnesium stearate are commonly used excipients for capsule fillers. Avicel 102 has good characteristics for a capsule filler, such as excellent flow ability in comparison to Avicel 101. Therefore Avicel PH 102 was mostly chosen as the capsule filler. Mg stearate was incorporated as lubricant, glidant and anti-adherent. These capsules were furthermore evaluated with respect to their dissolution behavior. The final product of the curcumin nanocrystal-loaded capsules can be seen in Figure 4.

In vitro dissolution testing of Curcumin capsules was performed in water and buffer at pH 1.2 and 6.8, at 37˚C (Figure 5). The dissolution test was not performed in sink conditions. Therefore at a certain time, release of Curcumin will be constant or further increase little because the saturation solubility is going to be approached.

Dissolution velocity of Curcumin from the Curcumin nanocrystal-loaded capsules (nanocrystal capsules) was distinctly improved and superior to that of micro crystals capsules. Within 30 minutes, almost all of Curcumin was dissolved from the nanocrystal capsules (Formulation A) in water and buffer having a pH of 6.8. However, only 50% Curcumin was dissolved in buffer having a pH of 1.2. In contrast, only less than half of Curcumin was dissolved from the microcrystal capsules (Formulation B) in water and in buffer having a pH of 6.8, and very little in buffer having a pH of 1.2.

Further studies were conducted in order to ascertain the efficacy of Curcumin nanocrystals against the marketed commercial Curcumin capsules. The commercial curcumin products available in the market also contain micro crystals of curcumin but in a typical unknown formulation. In order to make sure that the excipient used in our study does not add to the observed behavior and to have a direct comparison with market product further study was conducted to make certain the efficacy of Curcumin nanocrystals against the marketed commercial capsules. Figure 6 shows the dissolution behaviour of these two products in various medium. Due to the poor aqueous solubility of Curcumin, marketed capsules were unable to release Curcumin similar to microcrystal loaded capsules studied above. In contrast, Curcumin nanocrystals showed an increased kinetic solubility in all the medium studied. Therefore, the dissolve of Curcumin from these capsules was distinctly improved. After the initial nag period, nanocrystals showed near cent percent dissolution in water and at pH 6.8. At pH 1.2 it showed all most half of dissolution. In contrast the marketed commercial capsules containing Curcumin microcrystals showed very poor dissolution compared to nanocrystals in all the cases studied. Many researchers have evaluated the improved dissolution of Curcumin at 37˚C in distilled water and other body pH ranges [36]. The result shows that dissolution of Curcumin was considerably enhanced by solid dispersion of nanoparticles. However, their results did not specifically describe improved dissolution of Curcu min nanoparticles, instead mentioning only prolonged release of Curcumin from nanoparticles. Dissolution velocity of nanocrystal-loaded capsules is much better than any other techniques. Among factors for consideration,

nanocrystals are simpler to manufacture and require less material. Nanotechnology is therefore more effective in increasing solubility and dissolution velocity. Moreover this technology offers cost saving.

The more rapid release of Curcumin from the nanocrystal-loaded capsules is thought to be beneficial since, once being administered orally, the fast dissolved Curcumin may be passively partitioned into the gastrointestinal tract tissues in a shorter time (because of the favorable concentration gradient) resulting into a rapid onset of action and improved bioavailability. Therefore, Curcumin nanocrystal-loaded capsules offer promise for a dosage form with superior physicochemical properties

that overcomes problem of low bioavailability in the human body.

Compared to microcrystal capsule and marketed capsule, the nanocrystal capsules definitively showed higher levels of percentage dissolved curcumin. In all the dissolution media, nanocrystal capsules dissolved curcumin at distinctly faster rates compared to microcrystals and marketed capsules. Therefore, nanocrystal capsules have superior characteristics to microcrystals and marketed capsules, indicating a major opportunity to enhance the bioavailability of drugs by nanosuspensions for oral administration, in cases when dissolution is a rate limiting factor in bioavailability in the body like that of curcumin. It is easy to understand that a bio-relevant medium will need a similar surface activity as bio-fluids and hence a study on “In vivo pharmacokinetic evaluation of curcumin nanoformulation with improved bioavailability” was also carried out and is found to yield a similar positive result (communicated).

An outstanding feature of nanocrystals is the increase in saturation solubility and consequently an increase in the dissolution velocity of the compound. Based on the Noyes Whitney equation [37], this increase in dissolution velocity takes place in addition to the increase caused by the enlargement of the surface area, e.g. exploited in micronized products [38]. By decreasing the particle size (e.g. to the nanometer range), consequently the surface area of the particulate is further increased. In addition, the Noyes-Whitney equation also describes that the dissolution velocity dc/dt depends on the concentration gradient (cs is the saturation solubility; cx the equilibrium concentration in the bulk phase and h the diffusional distance) and the Prandtl equation describes that the diffusional distance h is reduced for small particles. Thus, the simultaneous increase in the saturation solubility cs and the decrease in h lead to an increased concentration gradient, enhancing the dissolution velocity in addition to the surface effect [39].

An increase in dissolution velocity and also an increase in saturation solubility can also be achieved by changing the crystalline state of the material (e.g. from crystalline to amorphous or partially amorphous). Due to thermodynamic reasons the preservation of the amorphous state is critical; therefore the production of nanocrystals should lead to crystalline particles. The crystalline state of the curcumin nanocrystals investigated in our study remained unchanged (100% crystalline) upon both, high pressure homogenization and drying process.

Recently, the particle size reduction effectiveness of drug substances-loaded tablets on oral bioavailability has been intensively investigated [23]. It has been proven that particle size reduction leads to improved oral bioavailability in the body. Takano et al. have specified that particle size reduction leads to improved dissolution rate and bioavailability [40]. In addition, the rate-limiting steps of oral absorption were simulated. An increase in the dissolution rate and administered dose showed a shift from dissolution rate-limited to solubility limited absorption. In the study in dogs, the particle size reduction of the drugs improved the oral absorption [40]. Such studies provide a powerful tool to predict dose linearity and will aid in the development of formulating poorly soluble drugs (Biopharmaceutical Classification System (BCS) class II (as well as IV) drugs).

According to Hintz et al., a computer method has been developed to describe the theoretical dissolution rate of a polydisperse powder under non-sink conditions based on its weight percent particle size distribution. It is shown that finer particles in the size distribution showed an improved dissolution behavior. Moreover the particle size distributions were used to simulate their effect on the amount of drug absorbed orally [41]. Similarly we suggest this promising curcumin capsule dosage form for oral administration. It leads to superior physicochemical properties and should overcome the in vivo absorption problem of the poorly soluble curcumin as class II BCS drug. Figure 7 summarizes the effects on bioavailability enhancement in the gut. Important is that the nanocrystals are released from the capsule or tablet as fine nanocrystals. It could be shown that a slight aggregation does not yet impair the dissolution velocity, but pronounced aggregation will decrease the dissolution velocity strongly [42].