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Design and evaluation of famotidine mucoadhesive nanoparticles for aspirin induced ulcer treatment

Dhaval J Patel Jayvadan K Patel About the authors


The present study was performed to design and evaluate the famotidine loaded mucoadhesive nanosuspension for aspirin induced ulcer. A 3-factor, 3-level Box-Behnken design was applied to study the effects of amount of the beads (X1), PVPK-30(X2) and Tween-80 (X3) on the particle size (Y1), and cumulative percentage drug released after 1h (Y2). The optimization was performed using the desirability function and contour plots. The scanning electron microscopy (SEM) showed the nanoparticles as spherical in shape. The differential scanning calorimetry (DSC) analysis indicated that there was substantial crystallinity change in the nanoparticle compared with the pure drug. Ex-vivo mucoadhesion study showed that famotidine mucoadhesive nanoparticles possessed higher mucoadhesion than the famotidine nanoparticles. The in vivo studies on aspirin-induced rats indicated the lowering in ulcer index for famotidine mucoadhesive nanoparticles was 0.46+0.011, which was significantly better than the effect of traditional famotidine suspension (0.66+0.035). Famotidine mucoadhesive nanosuspension could be prepared using the media milling technique and allowing significant reduction in ulcer index compared to famotidine suspension.

Famotidine; Nanosuspension; Box-Behnken design; Mucoadhesion; peptic ulcer


Design and evaluation of famotidine mucoadhesive nanoparticles for aspirin induced ulcer treatment

Dhaval J PatelI,** Author for correspondence:; Jayvadan K PatelII

IDepartment of Pharmaceutics; Saraswati Institute of Pharmaceutical Sciences; Gandhinagar; 382355, Gujarat, India

IIDepartment of Pharmaceutics; Nootan Pharmacy College; Visnagar, 384315, Gujarat, India


The present study was performed to design and evaluate the famotidine loaded mucoadhesive nanosuspension for aspirin induced ulcer. A 3-factor, 3-level Box-Behnken design was applied to study the effects of amount of the beads (X1), PVPK-30(X2) and Tween-80 (X3) on the particle size (Y1), and cumulative percentage drug released after 1h (Y2). The optimization was performed using the desirability function and contour plots. The scanning electron microscopy (SEM) showed the nanoparticles as spherical in shape. The differential scanning calorimetry (DSC) analysis indicated that there was substantial crystallinity change in the nanoparticle compared with the pure drug. Ex-vivo mucoadhesion study showed that famotidine mucoadhesive nanoparticles possessed higher mucoadhesion than the famotidine nanoparticles. The in vivo studies on aspirin-induced rats indicated the lowering in ulcer index for famotidine mucoadhesive nanoparticles was 0.46+0.011, which was significantly better than the effect of traditional famotidine suspension (0.66+0.035). Famotidine mucoadhesive nanosuspension could be prepared using the media milling technique and allowing significant reduction in ulcer index compared to famotidine suspension.

Key words: Famotidine, Nanosuspension, Box-Behnken design, Mucoadhesion, peptic ulcer


Among various noxious substances such as acid, pepsin, H. pylori, the use of non steroidal anti-inflammatory drugs (NSAIDs) plays a major role in the pathogenesis of peptic ulcer disease. The use of NSAIDs is the second most common cause of ulcers and the rate of NSAID-caused ulcers is increasing (Ibrahim et al. 2007; Hawkey (1990); Derle et al. 2006). Famotidine is H2-receptor antagonist widely prescribed in the gastric ulcers, duodenal ulcers, Zollinger-Ellison syndrome and gastro-esophageal reflux disease. Famotidine is reported to be 7.5 and 20 times more potent than ranitidine and cimetidine, respectively. Famotidine is classified as BCS class IV substance, since, drug of this class exhibits poor and variable bioavailability. The overall bioavailability is governed by several factors such as the rate of dissolution, intestinal permeability, gastric emptying and so on (Hassan et al.1990). A number of drugs remain poorly available when administered by the oral route. Among other reasons, this fact can be related either to, a low mucosal permeability for the drug or low solubility for the drug in the mucosal fluids. In both the cases, the drug absorption is poor, and an important fraction of the given dose is eliminated from the alimentary canal before being absorbed (Arangoa et al. 2001). The variability of absorption could also be reduced by their tendency to adhere to the gastrointestinal wall enabling rapid replenishment of the absorbed drug. To circumvent these problems, the drug nanoparticles system treated with mucoadhesive polymers has been proposed. These small particles have ability to penetrate in the mucus layer and bind to underlying epithelium and adhere directly to the mucus network. Thus, it may be expected that the particle uptake into the disrupted barrier in gastric ulcerations could allow the accumulation of the particulate carrier system in the desired area. Hence, subsequent increase in local drug concentration, prolongs the residence time of the drug in the gut and, therefore, increases the time when absorption can occur (Hasani et al. 2009).

Hence, the aim of present work was done to formulate and evaluate famotidine mucoadhesive nanosuspension for aspirin induce peptic ulcer treatment to overcome the problem of less contact time in ulceration. Famotidine nanosuspension was prepared using the media milling technique. Box-Behnken design was used to optimize the nanosuspension containing famotidine. The relationship between the dependent and independent variables was constructed using the contour plots. Then, the experimental design was combined with the desirability functions to predict the desired quality. The optimized famotidine nanoparticles were incorporated in physical admixture of mucoadhesive polymers (Hydroxyl propyl methyl cellulose/Sodium carboxymethylcellulose) dispersion to prolong their therapeutic effect. These combined systems were evaluated for mucoadhesion, rheological behavior, in vitro drug release and in vivo study.


Famotidine was obtained as a gift sample from Cadila Pharmaceutical, Gujarat, India. Polyvinylpyrrolidone (PVPK-30) was purchased from Sisco Research Laboratory, India. Tween-80 and Sodium carboxymethylcellulose (Na-CMC) were gifted by the S.D Fine Chemical Ltd, Mumbai, India. Hydroxyl propyl methyl cellulose-K4M (HPMC-K4M) was obtained as a gift sample from the Colorcon Asia Ltd, Goa, India. Double distilled water was prepared in the laboratory. All the chemicals used in the study were of analytical grade and used without further purification.

Box-Behnken experimental design

A Box-Behnken statistical design with three factors, three levels, and 15 runs was selected for the optimization study (Solanki et al. 2007). The experimental design consisted of a set of points lying at the midpoint of each edge and the replicated center point of the multidimensional cube. The independent and dependent variables are listed in Table 1. The polynomial equation generated by this experimental design (Microsoft excel, 2007) was as follows

Yi=bo+b1X1+b2X2+b3X3+b12X1X2+b13X1X3+b23X2X3+b11X12+b22X22+ b33X32 [1]

Here, Yi was the dependent variable, b0 was the intercept, b1 to b33 were the regression coefficients and X1, X2 and X3 were the independent variables that were selected from the preliminary experiments. After the fitting of the mathematical model, the desirability function was used for the optimization. The application of the desirability function combined all the responses into one variable and left the possibility to predict the optimum levels for the independent variables (Holm et al. 2006).

Preparation of nanosuspension

Nanosuspensions were prepared by the media milling method (Pandya et al. 2010). Zirconium oxide beads (ø 0.5 mm) were used as the milling media to prepare the aqueous nanosuspensions of famotidine at fixed concentration in 20 ml vials. All the batches were prepared according to the experimental design as shown in Table.1. The independent variables and their amounts were selected from the preliminary screening study (Patel et al. 2010). Also, in 20 ml vials, PVPK-30 was used as the polymeric stabilizer along with Tween-80 as non-ionic surfactant. The comminuting process was performed on a high-speed shaker (Remi, India) at 250 rpm at room temperature for 24 h. After milling, nanosuspensions were separated from the zirconium beads by decanting the suspension followed by washing of the beads with double distilled water. Milling was carried out under ambient conditions throughout the experiment.

Characterization of nanoparticles

Particle size and zeta potential analysis

Particle size analysis of the nano-suspension formulations was performed by the photon correlation spectroscopy using a Zetasizer 3000 (Malvern Instruments, UK). The formulations were added drop-wise to the sample dispersion unit containing water (saturated with famotidine) as a dispersant. A refractive index value of 1.5 was used for particle size analysis. Also, zeta potential for the optimized nano-suspension in distilled water was determined using the same equipment. All the data presented are the mean values of the results on three independent samples produced under the identical conditions.

SEM study

The surface morphologies of the micronized famotidine and optimized famotidine nanoparticles were visualized by the SEM. Particle morphology was investigated using a Hitachi (S-4700, Japan) with an acceleration voltage of 30 kV followed by coating with Pt-Pd for 2 min.

Preparation of famotidine loaded mucoadhesive nanosuspension

Table 2 shows the composition of all the mucoadhesive nano-suspensions. The HPMC-K4M and Na-CMC were dispersed gradually in separate container using double distilled water with slow magnetic stirring (Remi, India). Then, mucoadhesive dispersions were prepared by mixing the weighed quantities of Na-CMC (0.2, 0.4 and 0.6 %w/v) solutions with the HPMC-K4M (0.6, 0.4 and 0.2 %) solutions in 50ml glass beaker left to equilibrate for 24 h. The famotidine nanoparticles were then added to the HPMC-K4M and Na-CMC solution under constant stirring to obtain the uniform mixture and same for their polymer mixtures.

Rheological measurement

The viscosity of the mucoadhesive nano-suspensions was determined by the Brookfield viscometer (LV/M/00-151-E0808, MA, USA). Mucoadhesive nanosuspensions were filled in clean and dry test tube (Capacity 25 ml). The viscosity of the mucoadhesive nanosuspensions were determined at various rpm 6, 12, 30 and 60 using spindle no 3 and was calculated using the dial reading with its respective factor in repeated manner.

Mucoadhesion measurement

The shear stress measurement method, based on the measurement of shear stress required to break the adhesive bond between glass slides and the test formulation was used. The test formulation was sandwiched between the two glass slides fixed on flexible supports in the assemblies for a sufficient period of time. Water from a burette was allowed to fall in a beaker at a constant rate of 10 ml/sec. Increasing weight of water added gradually detached the two glass slides. Mucoadhesive force, the detachment stress (g), was determined from the minimal weights of water that detached the glass slides. The experiments were carried out in triplicates (Verma et al. 2009; Sheikh et al. 2009).

Thermal analysis

The optimized mucoadhesive nanodispersion was centrifuge at 10,000rpm for 10 min and the particle pellet was oven-dried at 50ºC for 24 h. Afterwards, it was used for the DSC analysis. The DSC scans of the famotidine and mucoadhesive nanoparticulate dispersion were recorded using the DSC-Shimadzu 60 (Shimadzu Co., Kyoto, Japan) with TDA trend line software. All the samples were weighed (8-10 mg) and heated at a scanning rate of 20°C/min under dry air flow (100 ml/min) between 50 and 300° C using the aluminum pans and lids for all the samples.

Drug release study

A double- jacketed beaker was used as a dialysis system to study the dissolution behavior of mucoadhesive nano-suspensions. The dissolution medium used was freshly prepared using 0.1 N HCL (pH 1.2). Dialysis membrane, previously soaked overnight in the dissolution medium was tied to one end of a specifically designed glass cylinder (open at both the ends) (Pandya et al. 2010; Lai et al. 2009). Five milliliter of the formulation was accurately placed into this assembly. The cylinder was attached to a stand and suspended in 300 ml of dissolution medium maintained at 37±1°C so that the membrane just touched the receptor medium surface. The contents of the beaker were agitated on a magnetic stirrer. Five milliliter of the sample was withdrawn periodically and replaced with an equal volume of fresh 0.1N HCl (pH 1.2) up to 8h. The samples were diluted suitably and filtered through a filter paper (0.22 µm, Whatman Inc., USA). The sample was then subject to the UV analysis against the blank (0.1NHCl solution). Percent cumulative release of famotidine was calculated based on the standard UV calibration curve at 267 nm (Systronic 2203, Japan).

Ex-vivo retention of mucoadhesive nano-suspension

Ex-vivo retention of mucoadhesive nano-suspension was adopted from the previously reported method (Rajinikanth et al. 2008). The approval of the Institutional Animal Ethics Committee was obtained before the starting the study. The stomach of the overnight fasted rats was removed and cut into pieces (2 cm long and 1 cm wide) and were rinsed with 2.0 ml of physiological saline and 5.0 ml of optimized mucoadhesive nanoparticulate dispersion. The nanoparticulate dispersion of drug were placed uniformly on the surface of the stomach mucosa and allowed to react with mucin for 15-20min. The mucosal lumen was rinsed with HCl-physiological saline at angle of 45°. The amount of formulation, which remained coated onto the tissues after rinsing in HCl-physiological saline was determined.

In vivo study

All the animal experiments were carried out in accordance with the recommendations of the Institutional Animal Ethics Committee of Shree Krishna Institute of Pharmacy Shankhalpur, Gujarat, India. Albino rats of both sexes (age:- 10-12 weeks and weighing 200-250 g) were used in all the experiments. Each group of the treated animals contained at least three rats and was housed in standard cages. Disease control (distilled water-10 ml/kg), famotidine marketed suspension (40mg/10ml/kg), and famotidine mucoadhesive nano-suspension (B3) (40 mg/10ml/kg) were arranged in groups 1, 2 and 3, respectively. Distilled water, famotidine and formulation B3 were given orally and 30min later aspirin (200mg/kg-per oral) was administrated to all the groups. Eight hours later, the animals were killed by decapitation. The stomachs were removed, opened along the great curvature and washed with the tap water to remove the gastric contents, then examined under a dissecting microscope with square-grid eyepiece to assess the formation of ulcers. For each stomach, ulcerated and total areas were measured as mm2. The ulcer indexes for each stomach were calculated using the following formula:

Ulcer Index = [Ulcerated area / Total stomach area] * 100

Stability study

The accelerated stability study was carried out according to the International Conference on Harmonization (ICH) guidelines (Shaikh et al. 2009). Sealed vials (10ml) of freshly prepared B3 formulation and famotidine nano-suspension were placed in stability chamber maintained at 25ºC±2°C/60% relative humidity (RH). The nanoparticles subjected to comparative stability tests were analyzed over three month's period for physical appearance, particle size and sedimentation of nanoparticles at frequency of 1 month sampling. In vitro release study of formulation B3 was also carried out after every one month.


Box-Behnken design and desirability function

From the preliminary experimentation, it was observed that the amount of the beads, amount of PVPK-30 and amount of tween-80 contributed much towards the change in Y1 and Y2 in nano-suspension preparation using the media milling method. Therefore, Box-Behnken design was applied in this study to optimize the famotidine nano-suspension with the constraints on the particle size and Q1. The transformed values of all the batches along with their results are shown in Table 3 (Solanki et al. 2007). The polynomial equations were used to draw the conclusions after considering the magnitude of coefficient and the mathematical sign it carried (i.e., positive or negative). The mathematical relationship in the form of factor's coefficients, its corresponding P-values for the measured responses and correlation coefficient are listed in Table 4. Coefficients with P-value less than 0.05 had a significant effect on the prediction efficacy of the model for the measured response. The high values of correlation coefficient for the dependent variables indicated a good fit. The particle size (dependent variable,Y1) obtained at various levels of the three independent variables (X1, X2, and X3) was subjected to multiple regression to yield a second-order polynomial equation (full model).

Y1= 524+30.10X1-54.09X2-39.39X3+41.00X1X2-7.30X1X3+42.30X2X3 +101.29X12+43.20X22-111.64X32 [2]

The particle size values measured for the different batches showed wide variation (i.e., values ranged from a minimum of 394.1 to a maximum of 742.0). The results clearly indicated that the particle size value was strongly affected by the variables selected for the study. This was also reflected by the wide range of values for the coefficients of the terms of equation 2. The main effects of X1, X2, and X3 represented the average result of changing one variable at a time from its low level to its high level. The interaction terms (X1X2, X1X3, X2X3, X12, X22, and X32) showed how the particle size changed when two variables were simultaneously changed. Concerning the particle size, the results of multiple linear regression analysis showed that both the coefficients b1 had positive sign while b2 and b3 had a negative sign (R2=0.9673). Equation 2 revealed X1 had the largest positive effect compared to X2 and X3. Among, the interaction terms, only b13 was non- significant (P >0.05) (Table 4). The significance level of coefficients b12 b13, and b22 was p = 0.052, 0.322, and 0.05 respectively, hence it was omitted from the full model to generate the reduced model. Coefficients b1, b2, b3, b23, b11 and b33 were significant at p < 0.05 hence, they were retained in the reduced model. The reduced model was tested in portions to determine whether the coefficients b2 and b12 contributed significant information for the prediction of Y1. The results of testing the model for ANOVA are shown in Table 5. The observed and predicted values with residuals and percent error of responses for Y1 are shown in Table 6. The critical value of f = 5.41 (p = 0.05) was higher than the calculated value (F =4.70).

It could be concluded that the interaction terms b12 b13, and b22 did not contribute significantly to the prediction of Y1, and the low coefficients for these terms in equation 2 indicated that these terms contributed the least to the prediction of Y1. Hence, these terms were omitted from the full model to obtain a reduced second-order polynomial equation 3 by multiple regressions of Y1 and the significant terms (p < 0.05) of equation 2, Y1 = 524+30.10X1-54.09X2-39.39X3+42.30X2X3+101.29X12- 111.64X32 [3]

This indicated that on increasing X1, Y1 increased. In the present study, high amount of beads imparted the energy to the system was extensively to break down the particles completely. Therefore, activated regions were generated which might be responsible for agglomeration and hence particle size increase on storage. Therefore, less amount of beads generated the energy imparted to the system was enough to cause the complete particle size reduction. Simultaneously, on other side increasing the amount of PVPK-30 or Tween-80 might decrease the particle size. The small particles, which spontaneously aggregated to decrease the surface energy, were stabilized by a layer of surfactant or/and protective polymer. Less amount of stabilizer induced the agglomeration or aggregation and too much stabilizer promoted the Oswald's ripening (Patravale et al. 2004; Patel et al. 2010). Particle size was decreased because the freshly created particulate surfaces were immediately coated by a layer of Tween80-PVPK-30, which prevented the broken particles from agglomerating. Concerning Q1, the results of multiple linear regression analysis showed that both the coefficients b1 and b3 had positive sign while b2 had a negative sign (R2=0.9639). It could be concluded from the equation 4 that X1 showed the largest positive effect compare to X2 and X3.

Y2=84.17+1.81X1-0.08X2+1.58X3-1.31X1X2-0.03X1X3-1.71X2X3 -0.96X12-2.02X22+2.97X32 [4]

This indicated that on either increasing X1 or X3, Y2 increased. As discussed earlier for particle size, small particles surfaces were immediately coated by the layer of surfactant or polymer, which prevented to aggregation. During the dissolution experiments, it was noticed that more amount of PVPK-30 retarded the drug release due to formation of viscous block on to particle surface. The improvement of dissolution rate in nanosuspension was possibly caused by the increased surface area, which enhanced strong hydrophilic character of the drug toward Tween-80 via improvement in wettability of the hydrophobic drug.

Therefore, increasing the amount of the beads or the amount of Tween-80 was expected to increase the drug release after 120 min. The relationship between the dependent and independent variables was further elucidated by constructing the contour plots. The effects of X1 and X2 with their interaction on particle size at a fixed level of X3 are shown in Figure 1. The plots were linear up to 550nm particle size, but above this value, the plots were nonlinear indicating a nonlinear relationship between X1 and X2. It was determined from the contour plot that a lower value of particle size (500nm) could be obtained with an X1 level range from –1 to 0, and an X2 level range from –1 to 0.5. It was evident from the contour graph that the intermediate level of X1 and X2 favored the particle size of nano-suspension. When the coefficient values of two key variables, X1 and X2, were compared, the value for the variable X1 (b1=30.10) was higher, indicating that it contributed the most to predicting the particle size. The negative effects of X2 on the nano-suspension decreased the particle size. Figure 2 shows the contour plot drawn at a fix level of X2. The contour plot of the particle size values were curvilinear and indicated that a 500nm particle size could be obtained for a combination of the two independent variables, the X1 level in the range of 1 to 0, and the X3 level in the range of 0 to 1. The possible explanation was that the Tween-80 strongly localized at the surface of particles reduced the interface free energy and provided mechanical barrier to coalescence, preventing the aggregation of the particles. Similarly, Figure 3 shows the contour plot plotted at fix level of X1. The plot corresponding to 500nm was nonlinear, but in a descending pattern with an increase in the amount of the PVPK-30 or Tween-80. The particle size close to 500 nm could be obtained with an X2 level range of –1 to 0 and an X3 level range of 0.5 to 1. All the contour plots for a particle size close to 500nm were nonlinear. This signified that there was no direct linear relationship among the selected independent variables. The aim of the optimization of pharmaceutical formulations is generally to find the levels of the variable that affect the chosen responses and determine the levels of the variable from which a robust product with high quality characteristics may be produced. All the measured responses that may affect the quality of the product should be taken into consideration during the optimization procedure (Holm et al. 2006; Gupta et al. 2010). It was evident from the polynomial equation and contour plots (Figures 1-3) that a high and low level of X1 could not target particle size close accordance with 500nm.

Hence, the medium level was selected as optimum for X1. The optimum formulation targeted the nano-suspension for 500nm particle size and more than 80% drug release within 1h. Using the desirability function and the contour plots shown in Figures (1-3), 0 level for the amount of the beads (X1), a 0 level of the amount of PVPK-30 (X2), and a 0.3 level of the amount of Tween-80 (X3) were selected as optimal. Using the desirability function, all the defined responses could be combined into one overall response, the overall desirability (Fig. 4). Based on equations (2 and 4), this should be particle size of 500 nm and drug release after 1h (Q1) of 84.96%. These calculated values were in close accordance with the experimental results obtained. The experimental results led to particle size of 498.5 nm and Q1 of 85.24%.

Characterization of optimized famotidine nanosuspension

The differences of the two famotidine forms were evident also in the morphological studies done by the SEM (Fig. 5). Micronized famotidine powder showed the particle size generally larger (2.5-50µm) than the famotidine prepared nanoparticles and had the different morphology. Famotidine micronized suspension crystals showed more irregular elongated shape, while famotidine nanoparticles were more regular and spherical. The media milling of the coarse crystals led to a change of the drug morphology.

Thus, the SEM analyses confirmed a change of drug crystal structure during the wet crushing process. The zeta potential is an important physicochemical characteristic of the nanoparticles. Zeta potential values in therange of −15 mV to −30 mV are common for well-stabilized nanoparticles (Pandya et al. 2010; Zidan et al. 2007). Famotidine micronized suspension had -3 mv zeta potential value. This was very less stable suspension due to rapid coagulation or flocculation due to larger particles compared to nano-suspension. Zeta potential of optimized nanosuspension was -14.8 mV (Fig. 6). Depending on the nature of the interaction of the stabilizers with the drug surface, the properties of adsorbed layer vary the zeta potential. The zeta potential value showed that the PVPK-30 and Tween-80 resulted in a complete coverage as they were better able to mask the negative charge on the drug particles.

Rheological behavior

Viscosity plays a vital role in the dispensing and formulation of nanoparticulate mucoadhesive dispersion. In order to treat the peptic ulcers effectively, the lesion should be in contact with the liquid mucoadhesive formulation for the required time. Therefore, the liquid can readily be applied to the affected region of the mucosa and their high viscosity and mucoadhesion will cause liquid to remain in contact with the lesions for the extended periods. Depending on the need, mucoadhesive nanoparticulate dispersions could be prepared using the individual polymer and binary combinations of HPMCK4M and Na-CMC in variable concentrations. The rheological data shown in Table 7 revealed that all the mucoadhesive nanoparticulate dispersions exhibited shear thickening behavior at low shear rates, followed by shear thinning at high shear. Among these formulations, the viscosity was decreased in following order: HPMCK4M/Na-CMC>Na-CMC>HPMCK4M. It was also found that HPMCK4M and Na-CMC showed synergistic effect in viscosity enhancing action. The highest viscosity was recorded for the formulation B3 of HPMCK4M/Na-CMC (0.2:0.6%). A reduction in the concentration of HPMCK4M from formulations B1 to B3 without compromising the rheological properties of the delivery system could be achieved by the addition of viscosity enhancing polymer such as Na-CMC. The HPMCK4M based mucoadhesive dispersions (B4-B6) had fluid like consistency.

Therefore, these could be readily lost from the point of application in peptic ulcer due to the natural movements of the membrane and surrounding structures. This could be attributed that it was hydrated immediately after the contact with the aqueous medium of nanosuspension. Moreover, it was observed that the increase in the polymer (HPMCK4M) level from 0.6 to 0.8% and to 1% for B4-B6 slightly enhanced the viscosity of the nano-suspension. Similarly, Na-CMC content was increased in B7-B9 formulations, and significant change in the viscosity of nanosuspension was observed. This might be due to change in the amount of the polymer from low to high level. More intimate contact between the particle of Na-CMC results in decreased mobility and the increase in resistance of the gel layer to flow and its erosion. In case of the formulations B7-B9, the concentration dependency of the viscosity was gradual and as concentration was increased, the systems underwent a sol–gel transition and their viscosity was increased proportionally. When amount of Na-CMC was higher than 0.6%, formulations B8 and B9 were became stiff gels, therefore this could not be able to resuspend the famotidine nanocrytals (Gupta et al. 2010). This finding might suggest that the HPMCK4M hydrated more rapidly than that of HPMCK4M and Na-CMC combination. The formulation B10 did not contain any mucoadhesive polymer and fluid like consistency. It did not generate sufficient viscosity of formulation so it was not essential to identify its results. Additional benefits were not achieved when micronized suspension had higher viscosity due to their bigger particles. It was noticed that they settled down rapidly even though higher viscosity of medium. Hence, the particle size was main governing factor for the physical stabilization of mucoadhesive nano-suspension.

Mucoadhesion measurement

The combination of ionic polymer such as Na-CMC and nonionic polymer such as HPMCK4M is known to provide the formulation with desired mucoadhesive properties (B3) (Singh et al. 2010). The mucoadhesion characteristics were affected by the mixing ratio of the mucoadhesive polymers. The highest detachment force was observed with the formulation B3 followed by B2 and B1 (Fig. 7). This type of interaction results from carboxylic groups of Na-CMC and hydrogen binding between the OH groups of HPMCK4M. Thus, HPMCK4M/Na-CMC dispersions might be adhering rapidly in contact with the hydrated mucous membrane. This may be led to increase the adhesive surface for maximum contact with mucin and flexibility for the interpenetration with mucin. It was noticed that mucoadhesion difference between formulations B1 and B2 did not reach significant level.

Thermal analysis

For the bulk material of famotidine, the melting process took place with maximum peak at 167.61ºC. The DSC thermogram of mucoadhesive dispersion showed an endotherm at 121.61ºC, which could be attributed to the melting of the drug (Fig. 8). The peak of famotidine in the formulation showed a slight shift to the lower temperature side. This could be due to a reduction in the particle size and an increase in the surface area. The transformation of a sharp to a broad DSC peak due to the melting of famotidine and decrease in the melting point is associated with numerous lattice defects and the formation of amorphous regions in which the drug is located (Pople et al., 2006).

In vitro drug release study

The cumulative percent of the drug released versus time profiles from the mucoadhesive nanoparticulate dispersion containing HPMCK4M 1% (w/w), Na-CMC 1% (w/w) and binary mixture of HPMCK4M/Na-CMC are shown in Figure 9. The results of drug release studies indicated that B3, B6, and B9 released 28.07, 33.85, and 46.71% of drug at the end of 1 h and 84.49, 94.05, and 97.70% of drug at the end of 8 h. Among these formulations, the release rate was decreased in the following order: HPMCK4M/Na-CMC>HPMCK4M> Na-CMC. These polymers have been well known to retard the drug release by swelling in aqueous media. Although Na-CMC and HPMCK4M had similar drug release profile, the release rate was higher with Na-CMC. This could be due to the difference in wettability between the HPMCK4M and Na-CMC which led to a favors in the entrance of water through the polymer (Reddy et al. 2003). The HPMCK4M and Na-CMC released the drug at a faster rate than did the HPMCK4M/Na- CMC. These could be attributed to the HPMCK4M/Na-CMC interaction, which facilitates rapid formation of a viscous gel layer upon hydration and this has been regarded as an essential first step in achieving the controlled drug release. The results indicated that the formulation B3 had a better ability to retain the drug than the individual polymer in the mucoadhesive nano-suspension and could be used as sustained release drug delivery system in peptic ulcer. The examination of the correlation coefficient 'r' indicated that the drug release followed the diffusion controlled mechanism from the mucoadhesive dispersion (B3), as the values of 'r' for zero order (0.9902) were higher in comparison to first order (0.9717) and Higuchi's square root of time (0.9858). To confirm the diffusion mechanism, the data were fit into Korsmeyer's equation. When plotted according to korsmeyer's equation, the formulation B3 also showed high linearity (R2 0.9706), with a comparatively slope (n) value of 0.5718. This n value, however, appeared to indicate a coupling of diffusion and erosion mechanisms, the so-called anomalous diffusion (Singh et al.2010). Hence, the diffusion coupled with erosion could be the mechanism for the drug release from B3 formulation.

Ex vivo retention study

The mucoadhesive nanoparticulate dispersion (B3) with highest in vitro mucoadhesivity was compared with famotidine nanoparticles suspension (W33) for ex vivo mucoadhesivity study. It was remarkable that formulation B3 showed 75.8±3.03% compared to 57.2±1.64% mucoadhesion of famotidine nanosuspension after rinsing with HCl-physiological saline. It was noticed that combination ionic polymer (Na-CMC) with non-ionic polymer (HPMCK4M) potentiate the mucoadhesive strength of famotidine nanoparticles (Singh et al. 2010). It could be attributed that hydrogen bond interaction between Na-CMC and HPMCK4M promote the mucoadhesive nanoparticles to retain after 6 hours on mucus components of tissue.

In vivo study

The disease controlled model in rat after the oral administration of aspirin establishes a stable ulcer for at least two days. This permits the characterization of the in-vivo deposition of the particulate carrier system under the influence of gastritis symptoms. After inducing the gastric ulcer, stomach were opened to get visual evidence of the ulceration and to characterize the differences to healthy tissue (Fig. 10). In the histological analyses, strong damages of the gastric tissue were observed. Additionally, it was observed that the stomach wet weight/body ratio increased compared to the healthy control group, which has been known as an indicator for inflammation. The behavior of the proposed nanoparticulate system was examined with respect to reduction in ulcer index and accumulation in the ulcerated gastric tissue after oral administration. Mucoadhesive nanoparticulate dispersion showed significant decrease in ulcer index (0.46+0.011) when compared with the control group (3.61+0.14) and famotidine suspension treated animal (0.66+0.035). Qualitatively, an increased adherence of the mucoadhesive nanoparticles was obtained in ulcerated tissue. A size dependant particle deposition in the gastrointestinal tract of healthy subjects as well as mucoadhesion have been reported in the literature depending on the particle surface properties (Hasani et al. 2009). In the present work, famotidine nanoparticulate surface properties were modified with mucoadhesive polymers. Ulcer index of mucoadhesive nanoparticulate dispersion treated animal was dramatically reduced compared to famotidine suspension treated animal. It was noticed that mucoadhesive nanoparticles with smallest diameter led to highest adhesion compared to the coarse particle of famotidine suspension. This could be attributed to the strong mucus production in the gastrointestinal tract, especially in the stomach, which favored the particle adhesion to the mucus. Mucoadhesive nanoparticles can better attach to mucus layer due to their small mass.

Stability study

Stability studies of the prepared nanosuspensions were carried out by storing the formulation B3 and famotidine nanosuspension at 25±2°C, 65±5% RH in humidity control oven for three months. The change in the particle size of formulation famotidine nanosuspension and famotidine mucoadhesive nanosuspension were investigated as the function of time to determine whether mucoadhesive polymers had better stabilizing efficiency. Famotidine nanosuspension particle size increased to 573.9±5.10, 638.8±8.73 and 734.9±6.30 respectively for each month of the analysis from first to third month.

The crystal growth could be due to Ostwald's ripening and was avoided by the addition of mucoadhesive polymers. Upon storage, famotidine mucoadhesive nano-suspension had particle size 578.7±7.51, 532.7±4.32 and 528.9±3.41 consecutively for three month analysis. The lower values at third month might be explainable by mucoadhesive polymer having sterically stabilizing effect after adsorption onto particle surface. Since adequate and uniform dosage is a prerequisite for any pharmaceutical suspension, the necessity of controlling the particle sedimentation is obvious. Famotidine nano-suspension showed 0.65±0.3 sedimentation volume (SV) ratio compared to 0.85±0.6 for the famotidine mucoadhesive after three months. Therefore, the famotidine mucoadhesive nano-suspension sediment was easily redispersed with soft agitation. On the other hand, famotidine nano-suspension was denser and it was more difficult to resuspend the sediment with vigorous shaking. This could be attributed to the particle size of famotidine nano-suspension, which increased due to Oswald's ripening. The settled particle arranged them into a hard packed cake, which resulted in the failure to obtain good degree of dispersion after three months. In vitro release study of selected mucoadhesive nanosuspension (B3) was carried out at 25±2°C/65%±5% RH after three months. Famotidine mucoadhesive nanosuspension was released 90.57±2.75% after 8 h. On comparing this data with the previous release data of B3 (Fig.9), it was observed that there was an overall increase in the drug release. These results could be attributed to the erosion of nanoparticles to some extent during the storage (Mishra et al. 2010).


The quality of famotidine loaded nanosuspension was presented using Box–Behnken design and desirability function. In vitro mucoadhesion and in vitro drug release studies clearly indicated that the prepared formulation possessed sufficient adhesion and prolong drug release characteristic up to 8h. Ex- vivo retention of mucoadhesive nanosuspension was higher compared to nanosuspension. Thus, apparently the surface modification of drug nanoparticles improved the retention of drug particles in upper intestinal tract. Moreover, the formulation was therapeutically effective against aspirin induced peptic ulcer. Mucoadhesive nanosuspension containing famotidine nanocrystals could produce added value by allowing a reduction in ulcer index compared to famotidine suspension.

Received: May 10, 2011;

Revised: July 10, 2012;

Accepted: December 17, 2012.

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    Publication Dates

    • Publication in this collection
      24 May 2013
    • Date of issue
      Apr 2013


    • Received
      10 May 2011
    • Accepted
      17 Dec 2012
    • Reviewed
      10 July 2012
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