Polymeric Recrystallized Agglomerates of Cefuroxime Axetil Prepared by Emulsion Solvent Diffusion Technique

Purpose: To study the effect of different polymers on the solubility and dissolution rate of cefuroxime axetil (CFU) prepared by emulsion solvent diffusion (ESD) technique. Methods: The ESD technique employed involved three test solvents: first, substance dissolution medium-good solvent (acetone); second, partial dissolution medium for the substance-bridging liquid (dichloromethane), and third, immiscible with the substance-poor solvent (distilled water). The pure CFU and the prepared agglomerates were characterized in terms of production yield, drug content, solubility, in vitro release profile, flowability, density, wettability, as well as by thin layer chromatography (TLC), differential scanning calorimetry (DSC), x-ray diffraction (XRD), Fourier transforms infra red spectroscopy (FTIR) and stability test. Results: DSC showed a decrease in the melting enthalpy indicating disorder in the crystalline content. XRD also indicated changes in crystallinity, FTIR revealed that there were no chemical changes in the recrystallized agglomerates while dissolution data demonstrated a marked increase in the dissolution rate (>55 % in 45 min) compared with the pure drug (35% in 45 min). The improvement in the dissolution rate of CFU from optimized crystal formulation was attributed to the wetting effect of the polymers, change in drug crystallinity, altered surface morphology and micronization. The recrystallized agglomerates also exhibited higher wettability and flowability. Conclusion: The optimised recrystallized agglomerates exhibited good solubility, wettability, dissolution rate and other physicochemical properties compared to the unmodified CFU.


INTRODUCTION
Aqueous solubility and dissolution are two of the crucial factors influencing drug absorption from the gastrointestinal tract (GIT).However, many newly discovered compounds exhibit low oral bioavailability.The oral route is convenient for administration of drugs compared to other routes; therefore, in developing novel oral drug delivery systems, different strategies are employed to increase the solubility and dissolution of liphophilic drugs, e.g., particle size reduction, solid dispersion, complexation with cyclodextrins, etc.Several methods of reducing particle size have been suggested.They include physical methods such as milling and grinding 1 , but it is difficult to obtain uniform fine particles and control the particle size of the drug.Microcrystallization of hydrophobic drugs is a technique to overcome these problems 2 .The process is usually used to obtain small particles by the disruption of large crystals Dissolution rate and bioavailability improvement by micronization of sparingly water-soluble drugs entail using jar mills and fluid energy mills 3 .
However, the micronization process is extremely inefficient due to the involvement of high energy nanoparticles and physical and/or chemical instability caused by disruptions in the crystal lattice [4][5][6] .Spray-drying of a drug solution is another way to produce micron-sized spherical particles.Spray-dried drugs, which are amorphous, show a smaller and more homogeneous particle size than mechanically micronized drugs 7,8 .However, as a fine particle fraction, even spray-dried amorphous drugs show only incomplete dispersion 9 .
The spherical crystallization technique has already been successfully applied to improve the micromeritic properties of acebutolol hydrochloride 10 .In the most common case, this technique is reputed to improve the wettability and dissolution rate of different drugs [11][12][13][14] .Some drugs have also been recrystallized by the spherical agglomeration technique using polymeric materials to modify their release
In the ESD method, the drug, and polymer and glyceryl monostearate were co-dissolved in an organic solvent mixture of dichloromethane (5ml) and acetone (5ml).The drug-polymer solution was slowly added to the external phase (150ml) containing 0.25% PVA under agitation at 1000 rpm.The system was stirred continuously for about 12 h.As the good solvent diffused into the poor solvent, droplets gradually solidified and formed spherical agglomerates.The system was filtered through Whatman filter paper no.42 under the vacuum to separate the spherical agglomerates.The resultant product was washed with distilled water and dried in a hot air oven at 40 0 C for 12 h.

Yield and drug content
The dried agglomerates were weighed and the production yield calculated.Each agglomerate (300mg) was powdered, from which a sample equivalent to 100 mg CFU was weighed and extracted with three portions of 50mL 0.07N HCl.Each portion was filtered through a G-4 sintered glass filter and volume was adjusted to 100 mL with the same extraction medium.After sufficient dilution with 0.07N HCl, samples were analyzed spectrophotometrically (Pharma Spec 1700, Shimadzu Corporation, Kyoto, Japan) at 281 nm and CFU content was calculated.The test was performed in triplicate.

Saturation solubility studies
Saturation solubility studies were carried out using deionized water as a solvent.Excessive quantity (sample 150 mg) of sample (pure drug or agglomerate) was taken in six screw capped test tubes with fixed volume (10 ml) of deionized water.The resultant suspension was shaken at room temperature in an incubator shaker at 100 rpm for 24 h after which samples were withdrawn and filtered through 0.2µ filters (Ultipor®N 66 , Pall Life sciences, Mumbai, India).The filtrate was suitably diluted with 0.07N HCl and analyzed at 281 nm by UV/VIS spectrophotometry.Triplicate measurements were made.

In vitro drug release study
The release rate of cefuroxime axetil and the agglomerates (sample equivalent to 100 mg drug) were performed in 900 ml of 0.07 N HCl using USP Apparatus II (Disso 2000, Lab India Pvt.Ltd, Mumbai, India) set at 37±0.2 0 C (n=6) and rotated at 55 rpm.Samples (5 ml) were withdrawn at regular intervals and replaced with the same volume of fresh dissolution medium to maintain sink conditions.The samples were suitably diluted with the dissolution medium and drug content assayed spectrophotometrically at 281 nm (Pharma Spec 1700, Shimadzu Corporation, Kyoto, Japan).

Measurement of flowability and density
The loose bulk density (LBD) and tapped bulk densities (TBD) were determined by using a density measuring apparatus (Serwell, Bangalore, India).An amount of the sample (5g) was placed in a measuring cylinder and the volume (bulk volume) was measured after applying three taps.Tapped density was measured as per USP using the procedure described by Lafaver 20 .A quantity (20g) of the material was passed through a 1 mm aperture sieve and transferred to a 100mL graduated cylinder.The surface was carefully leveled out compacting the material.The unsettled apparent volume was noted..The cylinder was tapped at a rate of 300 drops/min over a fixed drop distance of 14±2mm.After the first 500 drops, the volume of the material in the cylinder was measured.Further tapping (750 and then 1250 drops successively) was applied was applied until the difference between two volumes following successive tapping was less than 2.0%.This final volume was taken as the tapped volume.Bulk and tapped densities, Carr's index (%) and Hausner's ratio were calculated as in Eqs. 1 -4.Angle of repose of the materials were assessed by the fixed funnel method and computed as in Eq. 5.The results presented are the means of three determinations each.

Wettability study
Powder bed hydrophilicity test was carried out to assess the wettability of the agglomerates by placing the sample (2 g) in sintered glass tube to form a bed in the glass tube on which methylene blue crystals (≈100 mg) were placed.The tube was brought into contact with the surface of water and the time taken for water to rise by capillary movement to dissolve methylene blue crystals was noted.The shortest time corresponds to the most wettable sample.The test was performed in triplicate.

Differential scanning calorimetric (DSC) studies
Differential scanning calorimetric (DSC) analysis of the samples was carried out with a DSC analyzer (model TA-60, Shimadzu Corporation, Kyoto, Japan).A sample (3-7 mg) was sealed in an aluminum pan with a perforated lid and heated under nitrogen atmosphere at a heating rate of 10 °C/min over the temperature range of 20 -210 0 C. The thermograms were obtained and recorded.

X-ray powder diffraction (XRPD) studies
The XRPD patterns of the samples were monitored with an x-ray diffractometer (Philips PW 1729, Analytical XRD, Holland) using Ni filtered CuK(α) radiation (intensity ratio(α 1 / α 2 ): 0.500), voltage of 40 KV, current of 30 mA and receiving slit of 0.2 inches.The samples were analyzed over 2θ range of 5.010-39.990o with scanning step size of 0.020 o (2θ) and scan step time of one second.To minimize the effect of particle size on preferred orientation, all the samples were first passed through sieve no.120 (125µm) and collected on sieve no.240 (62.5µm).

Fourier transforms infra red spectroscopy (FTIR) studies
The FT-IR spectra of the agglomerates and the pure drug (embedded in potassium bromide pellet) were recorded on Shimadzu FTIR -8400 spectrophotometer (Shimadzu Corporation, Kyoto, Japan).Background spectrum was obtained under identical conditions.Each spectrum was derived from single average scans collected in the region 400 -4000 cm -1 at a spectral resolution of 2 cm -2 and rationed against background interferogram.The spectra were analyzed by the in-built software.

Statistical analysis
The data was analyzed using GraphPad InState Demo and Microsoft Excel 2003.One-way analysis of variance (ANOVA) and Dunnett Multiple Comparisons Test were used test the statistical significance of the data.P < 0.0001 was considered extremely significant.Variation among column means was significantly greater than expected by chance.If the value of q is greater than 2.880 then the P value is less than 0.05.

RESULTS
The physicochemical and other properties of the CFU and its agglomerates are listed in Table 1.The yield of the recrystallized agglomerates was between 88 and 92% while drug content was in the range 93-96%.The aqueous solubility of CFU in the agglomerates was between 1.33 and 1.59 mg/ml compared to 0.3 mg/ml for the pure drug.Thus, there was a significant improvement in solubility (P<0.01).
Flowability was assessed in terms of angle of repose, Carr's index and Hausnar ratio.The agglomerates had significantly lower angle of repose (P < 0.01) with the value in the range of 20.0 -22.6 0 as against 39.7 0 for CFU, due to the irregular shape of the crystals, which facilitated the uniform flow of crystals from the funnel.Carr's index results reveal that flowability of CFU was also significantly poorer (P < 0.01) than those of the agglomerates with the latter having lower Carr index than pure CFU.Hausner ratio data similarly indicate that the agglomerates exhibited better flowability than the pure drug.The wettability test results in Table 1 indicate that the agglomerates were significantly (P < 0.01) more wettable with a water-rising time of 6.9 -8.0 h compared to 13.0 h for the pure drug The order of wettability was CFU-RLPO > CFU-HPMC > CFU-HPC > CFU.
The in vitro drug release data, shown in Figure 1, revealed that drug release rates of the CFU agglomerates were largely similar but greater than that of the pure CFU.Powder X-ray diffraction patterns, displayed in Figure 2, indicate that pure CFU did not

DISCUSSION
The method used for the preparation of the CFU agglomerates was emulsion solvent diffusion (ESD) technique.In this method, when bridging liquid plus good solvent solution of the drug, along with different polymers, were poured into the poor solvent (dispersion medium) under agitation, quasiemulsion droplets of bridging liquid or good solvent form the emulsion droplet in the dispersing medium and induces the crystallization of the drug followed by agglomeration.The continuous phase is a liquid in which the drug solution is immiscible, and crystallization occurs inside the droplets because of counter diffusion of solvents through the droplets.The average diameter of the agglomerate crystals increased with increasing content of dichloromethane (DCM) in the system due to the enhanced agglomeration of powdery crystals.When the amount of acetone in the system was increased, while keeping the amount of DCM constant, the diffusion rate of acetone and DCM from the droplets was enhanced with increase in the content of acetone in the system.The increase in diffusion rate of DCM from the droplets shortened the agglomeration process of the crystals produced in the droplets while decrease in the DCM content of droplets reduced the agglomeration force of the crystal due to the increase in the unwetted part of the crystals with DCM in the agglomerates resulting in the formation of flocks with pendular bridges of water.Thus, the particle diameter and recovery of agglomerates decreased with increase in the acetone content of the system.

Physicochemical properties
The presence of the polymer, Eudragit, in CFU-RLPO enhanced the ability of the compound to form micelles, due to the presence of quaternary groups in the polymer, and thus increased the solubility of CFU.On the other hand, the presence of HPMC and HPC on the CFU particle surface would increase particle-particle interaction, thus causing faster squeezing out of DCM to the surface, and resulting in increased particle size and strength of agglomerates.Furthermore, improvement in the solubility of the agglomerates may also be due to changes in the crystal forms as well as changes in crystal habit, structure and surface modification.In some instances, solvents incorporated into the crystals form solvets or clathrate that changes surface properties, reactivity of drug particles and the internal energy of the molecules, which play important roles in solubility improvement.The addition of HPMC and HPC, which are watersoluble polymers as stated earlier, increases the solubility of CFU in water by adsorbing on to the drug particle surface during agglomeration.
The reason for the excellent flowability of the recrystallized agglomerates may be a reduction in interparticle friction as a result of probably a more spherical particle shape as well as larger crystal size.The rationale for the superior wettability of agglomerates is that the polymers adhere to the CFU crystals while their faster dissolution or release properties can be linked to their better wettability.
The agglomerates show slightly lower melting points than the pure drug but this may not be related to a change in the internal structure of the drug molecule.However, the change in the characteristic peaks and d-values can be linked to crystal habit modification while changes in the intensity of the peaks indicate a different arrangement of the molecules and hence suggest the development of new polymorphic forms.
In the FTIR study, the slight shift of the absorption band for the carbonyl group of the amide to a lower frequency can be attributed to the breakdown of the intermolecular hydrogen bond associated with the crystalline drug molecule and formation of hydrogen bond between the monomeric drug and the polymers.Overall, no changes occurred in the chemistry of CFU and there was no great fingerprint difference between CFU and the agglomerates.

Figure 3 : 1 , 1 ,
Figure 3: DSC thermograms of CFU and CFU agglomeratesThe FTIR results are illustrated in Figure4and they reveal that the peak at 1685.34 cm -

Figure 4 :
Figure 4: FTIR spectra of CFU and CFU agglomerates