Batch vs. continuous direct compression - a comparison of material processability and final tablet quality.

In this study, an in-depth comparison was made between batch and continuous direct compression using similar compression set-ups. The overall material processability and final tablet quality were compared and evaluated. Correlations between material properties, process parameters and final tablet properties were made via multivariate data analyses. In total, 10 low-dosed (1% w/w) and 10 high-dosed (40% w/w) formulations were processed, using a total of 10 different fillers/filler combinations. The trials indicated that the impact of filler type, drug load or process settings was similar for batch and continuous direct compression. The main differentiator between batch and continuous was the flow dynamics in the operating system, where properties related to flow, compressibility and permeability played a crucial role. The less consistent flow throughout a batch process resulted in a significantly higher variability within the tablet press (σCF) and for the tablet quality responses (σMass, σTS). However, the better controlled blending procedure prior to batch processing was reflected in a more consistent API concentration variability. Overall, the comparison showed the benefits of selecting appropriate excipients and process settings to achieve a specific outcome, keeping in mind some key differentiators between both processes.

The effect of carrier surface treatment on drug particle detachment from crystalline carriers in adhesive mixtures for inhalation.

In this study, the effect of lactose carrier surface treatment on drug particle detachment during inhalation has been investigated. Crystals of marketed brands of alpha lactose monohydrate brands normally exhibit a certain surface rugosity and contain natural fines and impurities on their surface, which influence the drug-to-carrier interaction in adhesive mixtures for inhalation. Submersion treatment may change these surface characteristics. Two different sieve fractions (63-90 and 250-355microm) were submerged in mixtures of ethanol and water (96 and 80% v/v, respectively). Microscopic observation and laser diffraction analysis revealed that neither the shape nor the size of the carrier particles was changed by the submersion treatment. However, the specific surface area and the amount of impurities appeared to decrease substantially after submersion, and the magnitude of the decrease was different for the different ethanol-water mixtures. The reduction in specific surface area was attributed particularly to the removal of the adhering lactose fines from the carrier surface. Mixtures with budesonide (in a wide range of carrier payloads) were prepared before and after treatment. Drug particle detachment from the various mixtures was studied with a sieve test and with a cascade impactor analysis at 30 and 60l/min. Two different types of inhalers were used, one generating lift- and drag-forces (ISF inhaler) and one generating inertial forces (test inhaler), respectively. The cascade impactor and sieve test experiments showed that an increase in carrier surface smoothness results in a reduced drug particle detachment during inhalation, which was independent of the type of inhaler used. This reduction could be attributed to the removal of the adhering lactose fines which may provide shelter for the drug particles from press-on forces during mixing.

A critical evaluation of the relevant parameters for drug redispersion from adhesive mixtures during inhalation.

In this paper, the parameters that are relevant to the drug redispersion from adhesive mixtures during inhalation are discussed and evaluated. The results obtained with air classifier technology give strong evidence for a dominating influence of carrier surface properties on the fraction of drug detached during inhalation at a low carrier payload (< or =1%, w/w), versus a dominating effect of carrier bulk properties at higher payloads. Furthermore, the results indicate that there is a fundamental difference between so-called active carrier sites and large surface discontinuities. The difference refers to the saturation concentrations, the rates of saturation and their effects on drug detachment during inhalation. The degree of saturation of the active sites appears to be proportional with the square root of the carrier surface payload (after 10 min mixing time in a Turbula mixer at 90 rpm). The storage volume of the discontinuities seems largely independent of the carrier diameter for particles derived from the same batch of crystalline lactose. Saturation of these discontinuities is completed at a much lower carrier surface payload than saturation of the active sites. Relatively large discontinuities are beneficial to de-agglomeration principles that make use of inertial separation forces during inhalation, as they provide shelter from inertial and frictional press-on forces during mixing which increase the strength of the interparticulate bonds in the powder mixture. For de-agglomeration principles generating frictional, drag or lift forces, carrier surface depressions and projections are disadvantageous however, as they also provide shelter from these removal forces.

The interaction between carrier rugosity and carrier payload, and its effect on drug particle redispersion from adhesive mixtures during inhalation.

The effectiveness of press-on forces (defined as the adhesive forces between drug and carrier particles) in relation to carrier payload as the result of collisions between carrier particles during the mixing process of an adhesive mixture, has been investigated. Three different carriers of the same size fraction (250-355 microm), but with completely different surface rugosity were studied. It could be shown that this effectiveness depends on the carrier rugosity. The fraction of drug detached from the carrier particles during inhalation appeared to decrease faster with increasing carrier payload for crystalline carriers than for granular carriers. Apparently, increasing the volume of the carrier surface cavities increases the drug mass that can find shelter from the press-on forces during mixing. By measuring the size distribution in the aerosol, it could also be shown that the press-on forces may increase the size of the particles that are detached. This seems to be the result of drug particle re-agglomeration on the carrier surface during mixing. On the other hand, when press-on forces are highly ineffective, an increase in the size of detached particles may also be the result of incomplete break-up of natural drug agglomerates. Finally, it could be shown that when the press-on forces are highly effective, the effect of mixing time is small.

The effect of carrier surface and bulk properties on drug particle detachment from crystalline lactose carrier particles during inhalation, as function of carrier payload and mixing time.

The effect of carrier payload and mixing time on the redispersion of drug particles from adhesive mixtures during inhalation for two different drugs (budesonide and disodium cromoglycate) has been investigated. A special test inhaler which retains carrier crystals during inhalation was used at 30 and 60 l/min. The special inhaler enabled the analysis of residual drug on the carrier yielding so called carrier residue (CR) values. Mixtures with carrier size fractions of 32-45; 150-200 and 250-355 microm, derived from marketed lactose brands, with increasing carrier payload (0.4-6.0% w/w of drug) were prepared. It was found that with increasing carrier payload, the CR increases for the coarse carrier fraction, decreases for the fine fraction and remains roughly constant for the intermediate fraction at 30 l/min. At 60 l/min, the CR decreased for all carrier fractions with increasing payload. The effect of powder bulk properties on the adhesive forces between drug and carrier (during mixing) as well as changes in the balance between adhesion and separation forces (during inhalation) explain the results found. An improved understanding of the different effects is obtained through the recently introduced force distribution concept. The ratio of (mean) separation force to (mean) adhesion force increases with the flow rate. The adhesive forces (during mixing) increase with increasing carrier diameter (higher press-on and kneading forces) and longer mixing time.

The effect of budesonide particle mass on drug particle detachment from carrier crystals in adhesive mixtures during inhalation.

The different fine particle fractions (FPFs) that are obtained, when different dry powder inhalers (DPIs) are used for the same powder formulation at the same flow rate, is the result of different powder de-agglomeration efficiencies for these DPIs. For adhesive mixtures, this is the efficiency with which the kinetic energy of the air flow through the DPI is converted into separation forces that detach drug particles from carrier crystals. We investigated the effect of drug particle diameter (mass) on drug-carrier separation during inhalation with three different inhalers (Sofotec Novolizer, Inhalator Ingelheim and a special test inhaler), at two different flow rates (30 and 60l/min). Two different size fractions were used as carrier material (45-63 and 100-150 microm). We measured decreasing amounts of residual drug on the carrier crystals after inhalation with increasing drug particle mass for all inhalers at both flow rates. The observed trends were the same for both carrier fractions. The decrease in residual drug on carrier is in agreement with increasing FPFs in an Erweka impactor. However, it has been calculated that the magnitude of the effect decreases with increasing de-agglomeration efficiency.