Characterization of khaya gum as a binder in a paracetamol tablet formulation

The influence of khaya gum, a binding agent obtained from Khaya grandifolia (Meliaceae family), on the bulk, compressional, and tabletting characteristics of a paracetamol tablet formulation was studied in comparison with the effects of two standard binders: polyvinylpyrrolidone (PVP; molecular weight 40,000) and gelatin. The relative ability of khaya gum to destroy any residual microbial contamination in the binder or in the formulation during tabletting was also studied using Bacillus subtilis spores as a model. Formulations containing khaya gum exhibited more densification than formulations containing PVP and gelatin during die filling, but less densification due to rearrangement at low pressures. The mean yield pressure of the formulation particles obtained from Heckel plots, and another pressure term, also inversely related to plasticity, obtained from Kawakita plots, showed dependence on the nature and concentration of the binder, with formulations containing khaya gum exhibiting the lowest and highest values respectively. The values of the pressure terms suggest that the yield pressure relates to the onset of plastic deformation during compression, while the Kawakita pressure relates to the total amount of plastic deformation occurring during the compression process. Tablets made from formulations containing khaya gum had the lowest tensile strength values but also the lowest tendency to laminate or cap, as indicated by their lowest brittleness. All the tablets had friability values < 1% at higher concentrations of the three binders. In addition, khaya gum demonstrated a comparable ability to destroy microorganisms in the formulation during tabletting as the two binders. The characterization of the formulations suggests that khaya gum can be developed into a commercial binding agent for particular tablets.     

Effects of Binders and Moisture Content on the Disintegration,Hardness and Friability of Paracetamol and Orphenadrine Citrate Tablets

Abstract

The effects of binders and moisture content on the disintegration time, friability and hardness of paracetamol and orphenadrine citrate tablets at different storage conditions were investigated. These parameters were determined after one, four and sixteen weeks of storage

The use of starch, ethocel or CMC Na as binders gave unsatisfactory tablets because of their high friability. Unacceptably high disintegration times were obtained, particularly at higher storage temperatures when PVP was used. Capping and yellow spotting observed in gelatin formulations makes this binder unsuitable for use. Methocel granulations yielded satisfactory tablets with acceptable disintegration time, hardness and friability and were unaffected by storage at different conditions of temperature and humidity     

Influence of capsule shell composition on the performance indicators of hypromellose capsule in comparison to hard gelatin capsules

The purpose of this study was to assess the in vitro performances of “vegetable” capsules in comparison to hard gelatin capsules in terms of shell weight variation, reaction to different humidity conditions, resistance to stress in the absence of moisture, powder leakage, disintegration and dissolution. Two types of capsules made of HPMC produced with (Capsule 2) or without (Capsule 3) a gelling agent and hard gelatin capsules (Capsule 1) were assessed. Shell weight variability was relatively low for all tested capsules shells. Although Capsule 1 had the highest moisture content under different humidity conditions, all capsule types were unable to protect the encapsulated hygroscopic polyvinylpyrrolidone (PVP) powder from surrounding humidity. The initial disintegration for all Capsule 1 occurred within 3?min, but for other types of capsules within 6?min (n?=?18). Dissolution of acetaminophen was better when the deionized water (DIW) temperature increased from 32 to 42?°C in case of Capsule 1, but the effect of temperature was not significant for the other types of capsules. Acetaminphen dissolution from Capsule 1 was the fastest (i.e. >90% in 10?min) and independent of the media pH or contents unlike Capsule 2 which was influenced by the pH and dissolution medium contents. It is feasible to use hypromellose capsules shells with or without gelling agent for new lines of pharmaceutical products, however, there is a window for capsule shells manufacturing companies to improve the dissolution of their hypromellose capsules to match the conventional gelatin capsule shells and eventually replace them.     

Effectiveness of Binders in Wet Granulation: A Comparison Using Model Formulations of Different Tabletability

Based on an analysis of model granulates and tablets, a comparison was made of the effectiveness of the binders PVP K30 PH, Cellulose HP-M 603, Lycatab DSH, Lycatab PGS, and L-HPC (type LH 11). A high shear mixer was used to prepare two model granulates (placebo and paracetamol) under processing conditions which were, as far as possible, comparable. The binders were added as proportions of 2%, 6%, and 10%. Water was used as the granulating liquid. The properties of the placebo granulates (particle size distribution, bulk and tapped density, granule strength, flow properties), and those of the tablets (crushing strength, friability) prepared from these granulates under different compaction forces, were generally good. However, with PVP, Cellulose HP-M603, and Lycatab, the disintegration time of the tablets did not meet pharmacopoeial requirements even though a “disintegrant” was used in the “outer phase.” The paracetamol formulations were prime examples of high-dose drug substances with particularly poor granulating and tabletting properties, well suited to reveal differences between the binders. The paracetamol granulates were of higher friability and less flowability than the placebo granulates. The tablets tended to cap, friability was (with few exceptions) high, and disintegration times were long. In the preparation of model tablets containing paracetamol, PVP K30 PH (6%). and Cellulose HP-M 603 (6%) turn out to be the binders of choice with respect to crushing strength, but the disintegration times are too long. Lycatab PGS, Lycatab DSH, and L-HPC-LH 11 could not be used to produce paracetamol tablets that met the requirements.     

Effects of Binders and Moisture Content on the Disintegration, Hardness and Friability of Paracetamol and Orphenadrine Citrate Tablets

The effects of binders and moisture content on the disintegration time, friability and hardness of paracetamol and orphenadrine citrate tablets at different storage conditions were investigated. These parameters were determined after one, four and sixteen weeks of storage

The use of starch, ethocel or CMC Na as binders gave unsatisfactory tablets because of their high friability. Unacceptably high disintegration times were obtained, particularly at higher storage temperatures when PVP was used. Capping and yellow spotting observed in gelatin formulations makes this binder unsuitable for use. Methocel granulations yielded satisfactory tablets with acceptable disintegration time, hardness and friability and were unaffected by storage at different conditions of temperature and humidity     

Effect of Storage Conditions on the Hardness, Disintegration and Drug Release from Some Tablet Bases

The effect of storage at relatively high temperature and humidity on tablets prepared from different bases was studied for up to eight weeks. Drug release from tablets was followed by measuring the concentration of a marker (amaranth) in the dissolution medium. Lactose and mannitol based tablets showed an increase in hardness and disintegration time, and a decrease in the initial rate of drug release. Sorbitcl based tablets, stored under 50°C/50% relative humidity (R.H.), showed a decrease in hardness and slower disintegration and dissolution. When stored under 40°C/90% R.H., the tablets were completely deformed within three days. Tricalcium phosphate and cellulose-based tablets did not show any storage related changes in hardness, disintegration or drug release.     

Effect of Crystallization of Theophylline on Physical Properties of Tablets

Tablets containing anhydrous theophylline, a hygroscopic material such as magnesium chloride or potassium acetate, and other constituents were stored for 4 and 12 weeks under 90% relative humidity at 37°C. During storage, whisker-like crystals appeared on the surface of the tablets. The crystals were observed under a scanning electron microscope. Changes were found in the physical properties of these tablets: crushing strength, friability, disintegration time and dissolution rate.     

Dissolution of Directly Compressed Thiamine Hydrochloride Tablets

Abstract

Directly compressed thiamine hydrochloride tablets with varying concentrations of different vehicles as well as their binary blends, were prepared for this investigation. The results showed that, formulated tablets with avicel anhydrous lactose and celutab completely dissolved within short times. First order mechanism was reported for the tablets prepared with single vehicles. The dissolution rate constant “K”, was a function of disintegration constant “D” of the tablets by the relation In K = a + n In D. In addition to that, it is proved that, “K” of produced tablets of short disintegration times was a function of the contributed vehicle concentration “C” by the relation, I/K = A exp. + NC.

On the other hand, (T 50%) of thiamine hydrochloride in a given batch was a function of its disintegration time.     

Effect of Storage Conditions on the Hardness,Disintegration and Drug Release from Some Tablet Bases

Abstract

The effect of storage at relatively high temperature and humidity on tablets prepared from different bases was studied for up to eight weeks. Drug release from tablets was followed by measuring the concentration of a marker (amaranth) in the dissolution medium. Lactose and mannitol based tablets showed an increase in hardness and disintegration time, and a decrease in the initial rate of drug release. Sorbitcl based tablets, stored under 50°C/50% relative humidity (R.H.), showed a decrease in hardness and slower disintegration and dissolution. When stored under 40°C/90% R.H., the tablets were completely deformed within three days. Tricalcium phosphate and cellulose-based tablets did not show any storage related changes in hardness, disintegration or drug release.     

Effect of Crystallization of Theophylline on Physical Properties of Tablets

Abstract

Tablets containing anhydrous theophylline, a hygroscopic material such as magnesium chloride or potassium acetate, and other constituents were stored for 4 and 12 weeks under 90% relative humidity at 37°C. During storage, whisker-like crystals appeared on the surface of the tablets. The crystals were observed under a scanning electron microscope. Changes were found in the physical properties of these tablets: crushing strength, friability, disintegration time and dissolution rate.     

Prelimnaky Evaluation of Cissus Root Gum as a Binder in Sodium Salicylate Tablet Formulations

Abstract

Cissus root gum was processed and evaluated as a binder in lactose-based tablets each containing 100 mg of sodium salicylate as the active ingredient. Acacia binder was used as basis for comparison. Tablet hardness, friability, disintegration time and dissolution rate were the parameters investigated. The cissus gum gave hard and non-friable tablets at 1 - 3% w/w concentration of the tablet formula. Tablets containing above 2% w/w of the cissus gum gave high disintegration time values and the pattern of dissolution of the incorporated drug suggests that the gum may be useful in prolonged release tablet formulations. No significant changes in the tablet properties was observed after storage at 30°C for 16 weeks.     

Application of a novel automatic disintegration apparatus for the development and evaluation of a direct compression rapidly disintegrating tablet

An automatic disintegration tester was developed and used to explore disintegration mechanism and times of rapidly disintegrating tablets. DT50, the time required for a tablet to decrease in its thickness by half, allowed an unbiased determination of disintegration time. Calcium silicate concentration, Explotab? concentration, DiPac?/Xylitab? ratio as fillers, and compression pressure were evaluated using a central composite model design analysis for their DT50, tensile strength, and friability. Tablets that could reasonably be handled (friability <10%) could be produced. The expansion coefficient (n) and the exponential rate constant (k) for disintegrating tablets, originally measured by Caramella et al. using force kinetics, could be determined from axial displacement data measured directly without the need to assume that disintegration force generation was indicative of changes in tablet volume. The n values of tablets containing calcium silicate, Ditab? and/or Xylitab?, magnesium stearate, and Explotab? suggested that the amount of Explotab? was not a significant factor in determining the disintegration mechanism; however, the type of disintegrant used did alter the n value. Primojel? and Explotab?, which are in the same class of disintegrants, exhibited similar DT50, n, and k. Polyplasdone? XL exhibited a much higher n, while yielding faster DT50, suggesting that its performance is more dependent on facilitating the interfacial separation of particles. AcDiSol? showed no apparent moisture sensitivity in regards to disintegration efficiency. The use of the novel apparatus proved to be useful in measuring disintegration efficiency of rapidly disintegrating tablets and in providing valuable information on the disintegration phenomena.     

Effect of Crospovidone on the Physical Properties of Acetaminophen Tablets

Abstract

Acetaminophen tablets containing minimum amount of excipients and varying amounts of cross linked polyvinyl pyrrolidone were prepared under accurately controlled conditions of compression speed and pressure. The disintegration time, dissolution rate, crushing force, friability as well as effect of temperature and humidity on these parameters during storage were determined. Increasing proportions of the cross linked polymer (1-10%) did not influence crushing force or friability but significantly decreased disintegration and dissolution time. Satishctory tablets with desired properties were obtained by incorporation of optimum quantity of crospovidone. Storage of acetaminophen tablets at room temperature and humidity for a period of 4 weeks did not alter any of the physical properties tested weekly. However the combined effect of elevated temperature and humidity on tablet properties, especially on the dissolution time was significant. The influence of incorporation of equal amounts of crospovidone intragranularly and intra-plus extragranularly on the properties of granules and tablets were also evaluated with scaled-up formulations.     

Effect of Crospovidone on the Physical Properties of Acetaminophen Tablets

Acetaminophen tablets containing minimum amount of excipients and varying amounts of cross linked polyvinyl pyrrolidone were prepared under accurately controlled conditions of compression speed and pressure. The disintegration time, dissolution rate, crushing force, friability as well as effect of temperature and humidity on these parameters during storage were determined. Increasing proportions of the cross linked polymer (1-10%) did not influence crushing force or friability but significantly decreased disintegration and dissolution time. Satishctory tablets with desired properties were obtained by incorporation of optimum quantity of crospovidone. Storage of acetaminophen tablets at room temperature and humidity for a period of 4 weeks did not alter any of the physical properties tested weekly. However the combined effect of elevated temperature and humidity on tablet properties, especially on the dissolution time was significant. The influence of incorporation of equal amounts of crospovidone intragranularly and intra-plus extragranularly on the properties of granules and tablets were also evaluated with scaled-up formulations.     

Physical Properties and Stability of Diazepam and Phenobarbitone Sodium Tablets Prepared with Compactrol

Abstract

Compactrol as a newly introduced direct compressible vehicle was used for the preparation of Diazepam and phenobarbitone sodium tablets. Spray dried lactose and wet granulation technique were also employed to prepare these tablets for comparison. The effect of storage at 75% RH, at two temperature levels (25° and 45°) on the physical properties of these tablets was studied for 6 weeks. It was found that, there were an increase in tablet weight, thickness and friability per cent, while a significant decrease in hardness was observed. Tablets prepared with compactrol showed no significant changes in both disintegration and dissolution times, while tablets prepared with spray dried lactose showed a marked decrease in disintegration and dissolution times. On the other hand, tablets prepared by wet granulation showed a pronounced in crease in both disintegration and dissolution times.     

The effect of moisture on the physical characteristics of ranitidine hydrochloride tablets prepared by different binders and techniques

Abstract

The effect of moisture on the physical properties of ranitidine hydrochloride tablets prepared by direct-compression and by wet-granulation method using PVP or EC as binders was studied. Tablets adsorped moisture at 50 and 75 % RH (relative humidity) but lost moisture at 30% RH. Except storage at 75% RH, however, tablet volumes did not change significantly during the test period. Moisture sorption caused a decrease in strength of tablets except low humidity (30% RH). Also, the disintegration time of tablets showed a decrease at all conditions except 30% RH. Furthermore, generally dissolution profiles of tablets prepared by direct-compression and by ethyl cellulose remained unchanged. Changes in the binder type in the tablet formulations changed the water uptake properties and also the physical properties of tablets. Directly-compressed tablets were much susceptible to change caused by humidity than tablets prepared by wet-granulation.     

Effects of pigeon pea and plantain starches on the compressional, mechanical, and disintegration properties of paracetamol tablets

A study has been made of the effects of pigeon pea starch obtained from the plant Cajanus cajan (L) Millisp. (family Fabaceae) and plantain starch obtained from the unripe fruit of Musa paradisiaca L. (family Musaceae) on the compressional, mechanical, and disintegration properties of paracetamol tablets in comparison with official corn starch BP. Analysis of compressional properties was done by using density measurements, and the Heckel and Kawakita equations, whereas the mechanical properties of the tablets were evaluated by using tensile strength (T--a measure of bond strength) and brittle fracture index (BFI--a measure of lamination tendency). The ranking for the mean yield pressure, P(y), for the formulations containing the different starches was generally corn < pigeon pea < plantain starch while the ranking for P(k), an inverse measure of the amount of plasticity, was pigeon pea < plantain < corn starch, which indicated that formulations containing corn starch generally exhibited the fastest onset of plastic deformation, whereas those formulations containing pigeon pea starch exhibited the highest amount of plastic deformation during tableting. The tensile strength of the tablets increased with increase in concentration of the starches while the Brittle Fracture Index decreased. The ranking for T was pigeon pea > plantain > corn starch while the ranking for BFI was corn > plantain > pigeon pea starch. The bonding capacity of the formulations was in general agreement with the tensile strength results. The disintegration time (DT) of the formulation increased with concentration of plantain and corn starches but decreased with concentration of pigeon pea starch. The general ranking of DT values was plantain < pigeon pea < corn starch. Notably, formulations containing pigeon pea starch exhibited the highest bond strength and lowest brittleness, suggesting the usefulness of pigeon pea starch in producing strong tablets with minimal lamination tendency. Plantain starch, on the other hand, would be more useful where faster disintegration of tablet is desired. The results show that the starches could be useful in various formulations depending on the intended use of the tablets with the implication that the experimental starches can be developed for commercial purposes.     

The effect of moisture on the physical characteristics of ranitidine hydrochloride tablets prepared by different binders and techniques

The effect of moisture on the physical properties of ranitidine hydrochloride tablets prepared by direct-compression and by wet-granulation method using PVP or EC as binders was studied. Tablets adsorped moisture at 50 and 75 % RH (relative humidity) but lost moisture at 30% RH. Except storage at 75% RH, however, tablet volumes did not change significantly during the test period. Moisture sorption caused a decrease in strength of tablets except low humidity (30% RH). Also, the disintegration time of tablets showed a decrease at all conditions except 30% RH. Furthermore, generally dissolution profiles of tablets prepared by direct-compression and by ethyl cellulose remained unchanged. Changes in the binder type in the tablet formulations changed the water uptake properties and also the physical properties of tablets. Directly-compressed tablets were much susceptible to change caused by humidity than tablets prepared by wet-granulation.     

The Effect of Low- and High-Humidity Aging on the Hardness, Disintegration Time and Dissolution Rate of Tribasic Calcium Phosphate-Based Tablets

The effect of low- and high-humidity aging on hardness, disintegration time and dissolution rate of tribasic calcium phosphate-based tablets prepared at different initial moisture levels was studied. The tablet hardness, disintegration time and dissolution rate of the drug changed only slightly on aging under low humidity when the moisture contents at the time of compression were low. At higher initial moisture levels, the tablet disintegration time decreased and the dissolution rate increased, although no change in tablet hardness occurred on aging under low humidity. The tablets containing lower initial moisture decreased in hardness, increased in disintegration time and decreased in dissolution rate on aging under high humidity. A small or variable change in hardness, a large increase in the disintegration time and a large decrease in the dissolution rate was seen in tablets containing higher initial moisture contents on aging under high humidity. The results indicate that the moisture content of the tablet granulation at the time of compression and moisture gained during aging plays a significantly important role on hardness, disintegration time and dissolution rate of tribasic calcium phosphate-based tablets.     

Influence of Storage Under Tropical Conditions on the Stability and Dissolution of Ascorbic Acid Tablets

Ascorbic acid tablets stored at 40°C and 90% R.H. demonstrated substantial changes in chemical as well as physical stability including color, disintegration time, hardness and dissolution rate. Tablets stored at 40°C and 35% R.H. showed virtually no change in chemical stability and hardness but measurable changes in disintegration time and dissolution rate. Moisture appeared to be a significant contributing factor to the enhancement of the chemical and physical instability of ascorbic acid tablets.