Application of moisture activated dry granulation (MADG) process to develop high dose immediate release (IR) formulations

Moisture activated dry granulation (MADG) method was used to develop IR tablets with cohesive, fluffy and high dose drugs. To evaluate this approach, three drugs: metformin hydrochloride, acetaminophen and ferrous ascorbate were selected as model compound along with three binders: maltodextrin DE16, PVP K 12 and HPC. The granules were generated using MADG method and tablets were prepared using rotary tablet press. The granules and tablets were characterized for particle size analysis, flow properties, tablet hardness, friability, moisture content, dissolution study, disintegration time and stability study. All results were found to be within acceptable limits. Development of all formulation tablets were found as best fitted for an immediate release of Metformin hydrochloride, acetaminophen and ferrous ascorbate. MADG delivered a robust manufacturing process for generation of granules with excellent flowability. The tablets prepared using this method were found to show better content uniformity, good compactability and low friability. Use of this approach aids to lower the amount of excipients used to overcome physiochemical limitation of the drug substances and there side effects. Both drying and milling steps in wet granulation were not required for MADG process. MADG became a cost effective process which could lead to reduced total tablet size and also save time.     

Carboxymethylstarches in Wet Granulation

Abstract

Commercialized carboxymethystarches (CMS) are both carboxyme-thylated and cross linked potato starch.

The influence of carboxymethylation and cross linkage on the disintegrating properties of starch are studied.

Tablets are made with acetaminophen as drug, Emcompress as diluant, Magnesium stearat as lubricant, and potato starch or its derivatives as disintegrants.

Tablets are prepared by direct compression or by wet granulation with the disintegrant intervening only in internal phasis.

Five disintegrants were studied, with two different concentrations:

native potato starch

potato starch simply cross linked

potato starch simply carboxymethylated

two potato starches both cross linked and carboxymethylated at two different degrees

Compressibility of powders blending and grain for compression are discussed.

The hardness, the tablet disintegration and the rate of drug dissolution are studied.

The results showed that the simply carboxymethylated starch has a totally different behaviour after direct compression or wet granulation. The poor results after wet granulation could be imputed to the bursting of starch granules during grain drying. Since it has lost its granular structure, the carboxymethylated starch will only allow a poor disintegration and a slow dissolution of the drug.

A very similar behaviour of native and simply cross linked starch: the results of which are bad for tablets either prepared by wet granulation or direct compression.

A very similar behaviour of the starches both carboxymethylated and cross linked, allowing a very good disponibility, either with tablets prepared by direct compression or wet granulation. These experiments prove :

the need for an sufficient cross linkage for CMS in a wet granulation process     

Carboxymethylstarches in Wet Granulation

Commercialized carboxymethystarches (CMS) are both carboxyme-thylated and cross linked potato starch.

The influence of carboxymethylation and cross linkage on the disintegrating properties of starch are studied.

Tablets are made with acetaminophen as drug, Emcompress as diluant, Magnesium stearat as lubricant, and potato starch or its derivatives as disintegrants.

Tablets are prepared by direct compression or by wet granulation with the disintegrant intervening only in internal phasis.

Five disintegrants were studied, with two different concentrations:

native potato starch

potato starch simply cross linked

potato starch simply carboxymethylated

two potato starches both cross linked and carboxymethylated at two different degrees

Compressibility of powders blending and grain for compression are discussed.

The hardness, the tablet disintegration and the rate of drug dissolution are studied.

The results showed that the simply carboxymethylated starch has a totally different behaviour after direct compression or wet granulation. The poor results after wet granulation could be imputed to the bursting of starch granules during grain drying. Since it has lost its granular structure, the carboxymethylated starch will only allow a poor disintegration and a slow dissolution of the drug.

A very similar behaviour of native and simply cross linked starch: the results of which are bad for tablets either prepared by wet granulation or direct compression.

A very similar behaviour of the starches both carboxymethylated and cross linked, allowing a very good disponibility, either with tablets prepared by direct compression or wet granulation. These experiments prove :

the need for an sufficient cross linkage for CMS in a wet granulation process     

A Study of the Compactibility Characteristics of a Direct Compression and A Wet Granulated Formulation of Norfloxacin

Compaction characteristics of norfloxacin tablets manufactured by both wet granulation and direct compression procedures were studied with the aid of an instrumented single punch tablet press interfaced with a digital computer. Under comparable tabletting conditions, the direct compression formulation required less compressional force than the wet granulated formulation to produce tablets of similar breaking strengths, which indicates superior compactibility. The directly compressed tablets were found to disintegrate faster and release their active component more rapidly during the critical early stages of dissolu-tion. Dissolution and disintegration of the directly compressed tablets generally were less affected by changes in breaking strengths than those compressed from granulated systems.     

Effects of manufacturing process variables on in vitro dissolution characteristics of extended-release tablets formulated with hydroxypropyl methylcellulose

The purpose of this study was to investigate the effect of three process variables: distribution of hydroxypropyl methylcellulose (HPMC) within the tablet matrix, amount of water for granulation, and tablet hardness on drug release from the hydrophilic matrix tablets. Tablets were made both by direct compression as well as wet granulation method. Three formulations were made by wet granulation, all three having the exact same composition but differing in intragranular:intergranular HPMC distribution in the matrix. Further, each formulation was made using two different amounts of water for granulation. All tablets were then compressed at two hardness levels. Dissolution studies were performed on all tablets using USP dissolution apparatus I (basket). The dissolution parameters obtained were statistically analyzed using a multilevel factorial-design approach to study the influence of the various process variables on drug release from the tablets. Results indicated that a change in the manufacturing process could yield significantly dissimilar dissolution profiles for the same formulation, especially at low-hardness level. Overgranulation could lead to tablets showing hardness-dependent drug-release characteristics. Studies showed that intergranular addition of a partial amount of HPMC (i.e., HPMC addition outside of granules) provided a significant advantage in making the formulation more robust over intragranular addition (i.e., that in which the entire amount of HPMC was added to the granules). Dissolution profiles obtained for these tablets were relatively less dependent on tablet hardness irrespective of the amount of water added during granulation.     

Tablet formulation of an active pharmaceutical ingredient with a sticking and filming problem: direct compression and dry granulation evaluations

Objective: To develop a tablet formulation for an active pharmaceutical ingredient for which sticking and filming problems occurred during tablet punching.

Methods: Direct compression and dry granulation tableting techniques were evaluated using factorial experimental design. The effects of chrome-coated punch tips, filler types and active percent in the tablet formulation by direct compression were evaluated. Similarly, for dry granulation using the roller compaction technique, three formulation factors – roller compaction pressure, intragranular filler percent and filler type – were studied. Tablets prepared by both techniques were characterized in regard to their compressibility index, tablet hardness, disintegration time, friability index and stickiness-filming index (an arbitrary index). Ten formulations were prepared by each technique. Using multiple response optimizations and estimated response surface plots, the data were analyzed to identify optimum levels for the formulation factors.

Results: Compressibility index values for all the formulations prepared by direct compression exceeded 25%, unlike the blends prepared by dry granulation. Both tablet hardness and disintegration time for direct compression formulations were significantly lower than for dry granulation formulations. The friability index values were significantly higher for direct compression formulations than for dry granulation formulations. All the direct compression formulations, unlike the dry granulation formulations, had a high stickiness-filming index.

Conclusion: Statistical analysis helped in identifying the optimum levels of formulation factors, as well as the method for eliminating sticking and filming. Unlike the direct compression technique, dry granulation yielded tablets for which sticking and filming were completely eliminated.     

The Effect of the Wet Granulation Process on Drug Dissolution

Abstract

Wet granulation can be an important processing step for pharmaceutical solid dosage forms. In this investigation emphasis was directed towards the influence of a “simple” wet granulation process on drug release from granules and their resulting tablets. Direct compression blends of the same materials were used as controls. Binary mixtures containing a 5% level of either theophylline, hydrochlorothiazide or chlorpheniramine maleate in microcrystalline cellulose or lactose were granulated with water. Experimentally, the powders were dry blended in a planetary mixer, wet granulated, and subsequently wet milled and dried. No dry milling step was included. Granule characterization consisted of particle size, density, porosity, compression and dissolution testing. Dissolution results varied with the drug, as expected, and dissolution at 10 minutes ranged from 35 to 95 % release. In general, however, the results indicate that dissolution from granules and the corresponding direct compression blend are similar. Although differences in compressibility were observed in the systems studied, granulation was not found to be detrimental to drug release.     

Factors Affecting Rate of Dissolution of Prednisone from Tablets

A study was carried out to evaluate some parameters which may have an effect on the dissolution rate of prednisone from tablets. The parameters examined involving formulation were: diluent proportion (Lactose-starch), dissintegrant type (starch, explotab (sodium starch glycolate) type of binder (starch paste, gelatine water solution and PVP alcoholic solution), lubricant, and dye concentration. The Manufacturing variables studied were: method of manufacture (wet granulation, direct compression and double compression), granule size in wet granulation and tablet hardness. dissolution profiles of tablets storaged 2 months at 45°C were compared with those of fresh samples. Tablets prepared with prednisone five years old, tablets with fresh active ingredient and tablets with two different prednisone concentrations (5 and 50 mg per tablet) were used for other evaluations.

In all cases micronized prednisone was used and all batches were physically and chemically evaluated before studying their dissolution following the USP basket method.

The parameters studied that affected significatively dissolution rate of prednisone were: type of binder, lubricant concentration, method of manufacture, active ingredient, age and prednisone concentration.     

Moisture-Activated dry Granulation in a high Shear Mixer

The applicability of a 25 litre high shear mixer for moisture-activated dry granulation was examined. Microcrystalline cellulose, potato starch or a mixture of 50% m/m of each was used as moisture absorbing material. The effects of water content, wet massing time, moisture absorbing material and dry mixing time on the size distribution, and the compressibility of the granulations were investigated. Tablets were compressed on a single punch press from all the granulations and on a rotary press from a few of the granulations.

It was shown that the physical properties of the tablets were primarily affected by the water content, the moisture absorbing material, and the compression force. Tablets with low mass variation, high crushing strength, low friability, and short disintegration time were achieved with both tablet presses by using a mixture of microcrystalline cellulose and potato starch as moisture absorbing material.     

Mixing of low-dose cohesive drug and overcoming of pre-blending step using a new gentle-wing high-shear mixer granulator

The objective of this study was to examine the influence of drug amount and mixing time on the homogeneity and content uniformity of a low-dose drug formulation during the dry mixing step using a new gentle-wing high-shear mixer. Moreover, the study investigated the influence of drug incorporation mode on the content uniformity of tablets manufactured by different methods. Albuterol sulfate was selected as a model drug and was blended with the other excipients at two different levels, 1% w/w and 5% w/w at impeller speed of 300?rpm and chopper speed of 3000?rpm for 30?min. Utilizing a 1?ml unit side-sampling thief probe, triplicate samples were taken from nine different positions in the mixer bowl at selected time points. Two methods were used for manufacturing of tablets, direct compression and wet granulation. The produced tablets were sampled at the beginning, middle, and end of the compression cycle. An analysis of variance analysis indicated the significant effect (p?相似文献   

Disintegration and Dissolution Parameters of Compressed Tablets Prepared by Direct Compression-Wet Granulation Process and Compression of Wet Granulation of Both Sections

Hardness, disintegration and dissolution of compressed tablets were assessed by compressing tablets from granulations prepared by dry and wet granulation process of two sections and by composite wet granulation process. Modified USP XVIII apparatus for disintegration, rotating basket apparatus USP XVIII and constant circulation apparatus were employed for measuring dissolution. The constant circulation apparatus was used in the studies as only it proved to be sensitive to reflect the differences in the dissolution rates and was a close analog of physiological situation. Four types of tablets containing acetylsalicylic acid, codeine phosphate and propoxyphene hydrochloride were prepared. Tablets prepared by partial dry and wet granulation process did not show significant differences in the rates of dissolution as compared to those prepared by complete wet granulation process.     

Granulation Rheology I: Equipment Design and Preliminary Testing

One of the most common pharmaceutical dosage forms is the compressed tablet, and of the several methods of preparing tablets, wet granulation remains widely used throughout the pharmaceutical industry. An apparatus was designed to follow the physical changes occurring in the granulation process. Its operation and preliminary results are presented.

As dry solid is wetted with granulating liquid, it passes through several stages, as it becomes wetter, it should exhibit a resistance to flow analagous to a viscous liquid. This resistance (force) can be measured. The test procedure follows the material from a dry powder through its maximum resistance and finally to a slurry. Such profiles could represent a characterization method for the solid and/or the liquid.

Materials tested included six common tablet excipients; these have been limited to single component granulations. Results indicate this apparatus is reproducible for these simple systems. Materials are shown to behave differently in the granulation process, and the apparatus appears capable of distinguishing between different materials.     

Factors Affecting Rate of Dissolution of Prednisone from Tablets

Abstract

A study was carried out to evaluate some parameters which may have an effect on the dissolution rate of prednisone from tablets. The parameters examined involving formulation were: diluent proportion (Lactose-starch), dissintegrant type (starch, explotab (sodium starch glycolate) type of binder (starch paste, gelatine water solution and PVP alcoholic solution), lubricant, and dye concentration. The Manufacturing variables studied were: method of manufacture (wet granulation, direct compression and double compression), granule size in wet granulation and tablet hardness. dissolution profiles of tablets storaged 2 months at 45°C were compared with those of fresh samples. Tablets prepared with prednisone five years old, tablets with fresh active ingredient and tablets with two different prednisone concentrations (5 and 50 mg per tablet) were used for other evaluations.

In all cases micronized prednisone was used and all batches were physically and chemically evaluated before studying their dissolution following the USP basket method.

The parameters studied that affected significatively dissolution rate of prednisone were: type of binder, lubricant concentration, method of manufacture, active ingredient, age and prednisone concentration.     

Alternative Granulation Technique: Melt Granulation

Abstract

A melt granulation process has been investigated (1, 2) which efficiently agglomerates pharmaceutical powders for use in both immediate- and sustained-release solid dosage forms. The process utilizes materials that are effective as granulating fluids when they are in the molten state. Cooling of the agglomerated powders and the resultant solidification of the molten materials completes the granulation process. Both the molten agglomeration and cooling solidification were accomplished in a high shear Collette Gral mixer equipped with a jacketed bowl. Hence, the melt granulation process replaces the conventional granulation and drying operations which use water or alcohol solutions. The melt granulation process has been investigated using immediate- and sustained-release TAVIST® (clemastine fumarate USP) tablet formulations. The TAVIST granulations have been characterized by power consumption monitoring, measurement of the granulation particle size distribution, bulk and tapped density determinations, and loss-on-drying measurements. Scale-up of the melt granulation process for the sustained release TAVIST tablet formulation was judged successful based on a comparison of the hardness, friability, weight uniformity during compression, disintegration time, and dissolution rate data obtained at different manufacturing scales.     

Evaluation of the Granulation of a Hydrophilic Matrix Sustained Release Tablet

Wet granulation of a hydrophilic sustained release matrix tablet formulation has been studied. A fractional factorial experimental design was employed to identify principal influences and interacting factors from the following : granulation fluid volume, mixing time, mixer speed and inclusion of a wet screening step. Fluid volume and mixing time were primary factors affecting mean granule size. Fines in the granulation were reduced at higher fluid levels and by inclusion of a wet screening operation. There were several interacting factors influencing the particle size properties of the granulation. The factors studied had little influence on the bulk density of the granulation.

The influence of granule mean particle size on flow, compressibility and drug release from finished tablets was evaluated. Flow and compressibility were influenced by granule properties and the data generated suggested that should final tablet properties deteriorate on scale up it may be possible to ameliorate the effect by modification of granulation fluid volume or mixing time or both.

The factors studies had no influence on release of drug from finished tablets.     

Disintegration and Dissolution Parameters of Compressed Tablets Prepared by Direct Compression-Wet Granulation Process and Compression of Wet Granulation of Both Sections

Abstract

Hardness, disintegration and dissolution of compressed tablets were assessed by compressing tablets from granulations prepared by dry and wet granulation process of two sections and by composite wet granulation process. Modified USP XVIII apparatus for disintegration, rotating basket apparatus USP XVIII and constant circulation apparatus were employed for measuring dissolution. The constant circulation apparatus was used in the studies as only it proved to be sensitive to reflect the differences in the dissolution rates and was a close analog of physiological situation. Four types of tablets containing acetylsalicylic acid, codeine phosphate and propoxyphene hydrochloride were prepared. Tablets prepared by partial dry and wet granulation process did not show significant differences in the rates of dissolution as compared to those prepared by complete wet granulation process.     

Alternative Granulation Technique: Melt Granulation

A melt granulation process has been investigated (1, 2) which efficiently agglomerates pharmaceutical powders for use in both immediate- and sustained-release solid dosage forms. The process utilizes materials that are effective as granulating fluids when they are in the molten state. Cooling of the agglomerated powders and the resultant solidification of the molten materials completes the granulation process. Both the molten agglomeration and cooling solidification were accomplished in a high shear Collette Gral mixer equipped with a jacketed bowl. Hence, the melt granulation process replaces the conventional granulation and drying operations which use water or alcohol solutions. The melt granulation process has been investigated using immediate- and sustained-release TAVIST® (clemastine fumarate USP) tablet formulations. The TAVIST granulations have been characterized by power consumption monitoring, measurement of the granulation particle size distribution, bulk and tapped density determinations, and loss-on-drying measurements. Scale-up of the melt granulation process for the sustained release TAVIST tablet formulation was judged successful based on a comparison of the hardness, friability, weight uniformity during compression, disintegration time, and dissolution rate data obtained at different manufacturing scales.     

Moisture-Activated dry Granulation in a high Shear Mixer

Abstract

The applicability of a 25 litre high shear mixer for moisture-activated dry granulation was examined. Microcrystalline cellulose, potato starch or a mixture of 50% m/m of each was used as moisture absorbing material. The effects of water content, wet massing time, moisture absorbing material and dry mixing time on the size distribution, and the compressibility of the granulations were investigated. Tablets were compressed on a single punch press from all the granulations and on a rotary press from a few of the granulations.

It was shown that the physical properties of the tablets were primarily affected by the water content, the moisture absorbing material, and the compression force. Tablets with low mass variation, high crushing strength, low friability, and short disintegration time were achieved with both tablet presses by using a mixture of microcrystalline cellulose and potato starch as moisture absorbing material.     

Continuous high-shear granulation: Mechanistic understanding of the influence of process parameters on critical quality attributes via elucidating the internal physical and chemical microstructure

Over the past decade, continuous wet granulation has been emerging as a promising technology in drug product development. In this paper, the continuous high-shear mixer granulator, Lӧdige CoriMix® CM5, was investigated using a low-dose formulation with acetaminophen as the model drug. Design of experiments was deployed in conjunction with multivariate data analysis to explore the granulator design space and comprehensively understand the interrelation between process parameters and critical attributes of granules and tablets. Moreover, several complementary imaging techniques were implemented to unveil the underlying mechanisms of physical and chemical microstructure in affecting the tablet performance. The results indicated that L/S ratio and impeller speed outweighed materials feeding rate in modifying the granule and tablet properties. Increasing the degree of liquid saturation and mechanical shear input in the granulation system principally produced granules of larger size, smaller porosity, improved flowability and enhanced sphericity, which after compression generated tablets with slower disintegration process and drug release kinetics due to highly consolidated physical microstructure. Besides, in comparison to batch mixing, continuous mixing integrated with a conical mill enabled better powder de-agglomeration effect, thus accelerating the drug dissolution with increased surface area.     

Use of a Moist Granulation Technique (MGT) to Develop Controlled-Release Dosage Forms of Acetaminophen

The moist granulation technique (MGT), which involves agglomeration and moisture absorption, has only been applied to immediate-release dosage forms. Our results indicate that MGT appears to be applicable in developing a controlled-release formulation. A small amount of granulating fluid (water) was added to a powder blend to activate a dry binder (such as polyvinylpyrrolidone [PVP] at 2% and 3.6%) and to facilitate agglomeration. Then, a moisture-absorbing material (microcrystalline cellulose [MCC]) was added to absorb any excess moisture. By adding MCC in this way, a drying step was not necessary. Acetaminophen (APAP) was the model drug, with diluents lactose FastFlo® and dicalcium phosphate. Hydroxypropylcellulose (HPC) was used as the controlled-release agent. The MGT was compared to conventional wet granulation (WG) and direct compression (DC) processing methods. The results indicate that MGT appears to be applicable in developing a controlled-release formulation. Particle size distribution of MGT and WG batches containing 3.6% PVP is similar.