Formulation, Optimization, in vitro and in-vivo evaluation of levofloxacin hemihydrate Floating Tablets

Abstract The objective of the present investigation was to design, optimize and characterize the gastro retentive floating levofloxacin tablets and perform in-vivo evaluation using radiographic imaging. The floating tablets were prepared by using polymers i.e hydroxy propyl methyl cellulose (HPMC-K4M) and carbopol-940 individually and in combination by nonaquous granulation method. All the Formulations were evaluated for swelling index (S.I), floating behavior and in-vitro drug release kinetics. The compatibility study of levofloxacin with other polymers was investigated by FTIR, DSC, TGA and XRD. Results from FTIR and DSC revealed no chemical interaction amongst the formulation components. The optimized formulation (F11) showed floating lag time (FLT), total floating time (TFT) swelling index (S.I) of 60 sec, >16h and approximately 75 %, respectively. Moreover, F11 showed zero order levofloxacin release in simulated gastric fluid over the period of 6 h. X-ray studies showed that total buoyancy time was able to delay the gastric emptying of levofloxacin floating tablets in rabbits for more than 4 hours. In conclusion the optimized formulation (F11) can be used for the sustained delivery of levofloxacin for the treatment of peptic ulcer.

Effect of precipitation inhibitors on pH-induced supersaturated phase behavior of dl-tetrahydropalmatine / 中草药

Objective: To investigate the effect of three types of precipitation inhibitors (PPI) HPMC K4M, HPMC AS MG and Soluplus on the pH-induced supersaturated phase behavior of dl-tetrahydropalmatine (dl-THP) at oral clinical doses. Methods: dl-THP pH solubility phase diagram and desaturation curve during pH-shift were drawn, and the solubility phase diagram was used to support dl-THP phase behavior. Area under the concentration-time curve and supersaturation ratio were used to analyze the effect of PPI on the phase behavior of dl-THP; Polarized light microscope and differential scanning calorimetry were used to analyze the precipitation properties. Results: Under the clinical dosage, the maximum supersaturation of dl-THP during the pH-shift was 3.93, and the supersaturation was lost over time; HPMC K4M, HPMC AS MG, and Soluplus could all maintain the supersaturation within 180 minutes during the pH-shift dissolution. HPMC K4M, HPMC AS MG, and Soluplus maintained supersaturation levels of 1.19, 1.89 and 1.36 respectively at a concentration of 5%, 1.30, 2.35 and 1.86 at a concentration of 20%, and 1.30, 2.60 and 2.07 at a concentration of 50%. Polarized light microscopy and differential scanning calorimetry results showed that crystalline precipitation occurred. Conclusion: All precipitation inhibitors can improve the pH-induced supersaturated phase behavior of tetrahydropalmatine, and this improvement behavior varies with the type and concentration of precipitation inhibitors. HPMC AS MG has the best effect.

Formulation and evaluation of a mucoadhesive buccal tablet of mefenamic acid

Buccal route of administration has many advantages such as improving patient compliance, bypassing the GIT and hepatic first pass effect. The objectives are to formulate mucoadhesive buccal tablet using Mefenamic acid and compatible excipients, and to evaluate the product using quality control tests and in vitro tests. The ingredients were subjected to Differential Scanning Calorimetry and Fourier Transform Infrared Spectroscopy studies for compatibility test and the results showed no interaction. Two batches of mefenamic buccal tablet were prepared. The tablet thickness and diameter are 3.75 mm and 12 mm respectively. All tablets are within the specification of +/- 5%. The in-house tablet hardness is 6.8-15kg and percent friabilation is not more than 0.8%. The disintegration test showed that all tablets disintegrated within 4 hours. The content uniformity showed that tablets are within the range of 85%-115%. The tablet weight is within the 5% range. The percent swelling is 53.83% to 58.86% and moisture absorption is 14.79% to 15.56%. The surface pH of the tablet is close to the salivary pH, which means that it would not irritate the buccal mucosa. The buccal tablet has a mucoadhesiveness of 0.196 to 0.200. There was no change in pH and size after subjecting it to stability studies in human saliva. Drug release studies showed 80.7% to 83.4% after 3 hours. Even after 3 months of subjecting the tablets to 40 ºC and 75% RH, results are within acceptable range. The results show the potential of the formulation as a mucoadhesive buccal tablet.

Formulation And Evaluation Of Garlic Powder Loaded Floating Matrix Tablet

Objective: The objective of the present work was to formulate and evaluate a stable, odour free garlic powder loaded floating matrix tablet for the treatment of peptic ulcers. Methods: A gastro-retentive floating matrix tablet (FMT) formulation of garlic powder (GP) was prepared using various concentrations of hydroxypropyl methylcellulose K4M (HPMC K4 M) and effervescent system (sodium bicarbonate and citric acid in 1:1 % w/w) to achieve desirable floating time (FT), floating lag time (FLT) and drug release. Wet granulation method was selected using ethanol as a binder for preparation of tablet. 32 full factorial designs were used for selection of suitable polymer concentration and effervescent system. Nonenteric film coating was applied to mask GP odour. Results: It was observed that FMT with optimum quantities of HPMC K4M and the effervescent system showed 97 % of drug release in 12 h with FT up to 10 h and minimum FLT of 3 min. There was no significant change in FLT, FT and drug content during the stability study of FMT. Conclusion: A stable, sustained release FMT of GP tablets using HPMC K4M and an effervescent system was successfully prepared. This formulation can overcome problems of taste and odour masking, gastric irritation, and loss of active constituents present in garlic.

Estimation Of Bacoside-A In Bacopa Monnieri Aerial Parts Using Tlc Densitometry

Objective: The objective of the present work was to formulate and evaluate a stable, odour free garlic powder loaded floating matrix tablet for the treatment of peptic ulcers. Methods: A gastro-retentive floating matrix tablet (FMT) formulation of garlic powder (GP) was prepared using various concentrations of hydroxypropyl methylcellulose K4M (HPMC K4 M) and effervescent system (sodium bicarbonate and citric acid in 1:1 % w/w) to achieve desirable floating time (FT), floating lag time (FLT) and drug release. Wet granulation method was selected using ethanol as a binder for preparation of tablet. 32 full factorial designs were used for selection of suitable polymer concentration and effervescent system. Nonenteric film coating was applied to mask GP odour. Results: It was observed that FMT with optimum quantities of HPMC K4M and the effervescent system showed 97 % of drug release in 12 h with FT up to 10 h and minimum FLT of 3 min. There was no significant change in FLT, FT and drug content during the stability study of FMT. Conclusion: A stable, sustained release FMT of GP tablets using HPMC K4M and an effervescent system was successfully prepared. This formulation can overcome problems of taste and odour masking, gastric irritation, and loss of active constituents present in garlic.

Formulation and characterization of ternary complex of poorly soluble duloxetine hydrochloride.

Duloxetine hydrochloride (DXH) suffers from poor solubility and thereby poor absorption, which ultimately leads to poor bioavailability. In present study, an attempt has been made to formulate and characterize duloxetine hydrochloride (DXH) complex, using β-cyclodextrin (β-CD) and different hydrophilic polymers in order to enhance its solubility and dissolution rate. Phase solubility study was used to investigate the interaction of the drug in binary systems (DXH-β-CD) as well as ternary systems (DXH-β-CD-hydrophilic polymer). It was observed that solubilization of DXH by β-CD was further enhanced by using HPMC K4M at 0.1% w/v concentration. Several methods were used to prepare ternary complex of DXH-β-CD-HPMC K4M. Ternary complex prepared by co-evaporation method containing DXH-β-CD-HPMC K4M in the ratio of 1:1.10:0.01 has shown the fastest dissolution rate (53.65 ± 2.83% in 5 min) as compared to pure DXH (3.03 ± 1.88% in 5 min) as well as other methods used to prepare these complexes. The prepared ternary complex system was characterized by the help of X-ray powder diffraction studies, differential scanning calorimetry and scanning electron microscopy. It was observed that enhancement in solubility as well as dissolution rate of DXH was due to formation of ternary complex system.