Approach to differentiate between hyaluronic acid skin quality boosters and fillers based on their physicochemical properties.

BACKGROUND: The clinical indications, applications, and effect of the injectable hyaluronic acid range skin quality boosters (SQBs) are different than those of filler products. Material properties are increasingly being discussed for differentiation and in connection with clinical effects and esthetic indications. AIMS: The aim of this study is to evaluate whether SQB products can be differentiated from filler products by their physicochemical material properties. MATERIAL AND METHODS: Physicochemical properties (extrusion force, swelling degree, rheology, and cohesivity) of two SQBs (BELR , JUVVE ) were compared with those of fillers (BELB , JUVVT ) using the same manufacturing technology. RESULTS: Cohesivity was almost equal for SQBs and fillers. Few statistically significant differences in physicochemical properties were found. Properties of SQBs differed from fillers mainly in their delta of rheological properties and extrusion force. CONCLUSION: In this study, physicochemical differences between SQB and filler were determined and described, supporting the presence of two categories and their different clinical indications and applications.

A novel approach to avoid capping and/or lamination by application of external lower punch vibration.

Capping as well as lamination are two common problems, which affect the resulting product quality of the tablet. Usually, capping and lamination occur during or after tablet manufacturing, and may therefore influence follow-up processes such as the coating. In this context, there is an urgent need for approaches to overcome the occurrences of capping and lamination. In the present study, a novel lower punch vibration technique was used to decrease the capping or lamination tendency of different powder formulations. Different microcrystalline cellulose types, as well as an API (acetaminophen), were selected as model powders. The powders were investigated regarding their powder flow, density, particle morphology, and surface area. Moreover, the manufactured tablets were characterized regarding their tablet weight, tensile strength, and capping or lamination indices. It was shown that the capping or lamination tendency was strongly affected by the physical powder properties, the formulation composition, and the adjusted turret speed. In addition, the application of externally applied lower punch vibration led to a pronounced decrease of the capping or lamination tendency and improved mechanical stability of the manufactured tablets.

Application of Externally Applied Lower Punch Vibration and its Effects on Tablet Manufacturing.

PURPOSE: In the present study the influence and application of a newly developed external lower punch vibration system for an improved die filling on a running rotary tablet press was investigated. METHODS: Tablets were manufactured at different conditions (with and without vibration) and characterized regarding their direct compressibility and mechanical stability. Thus, two typical pharmaceutical binders for direct compression (Parmcel 102 and Tablettose® 80) were compared with two binders unsuitable for direct compression (Ceolus® KG1000 and GranuLac® 200). The powders were characterized by helium pycnometry, laser diffraction, scanning electron microscopy, and by determination of the powder flow. Furthermore, a novel technique to determine the occurrences of segregation within a tablet after manufacturing was introduced. For this purpose, a powder blend containing one spray-colored type of microcrystalline cellulose (Vivapur® 200) were prepared. RESULTS: It was shown that under application of externally applied lower punch vibration, the powder flow into the die increased and thus the die filling process was significantly improved. Hence, it was possible to manufacture tablets from powders, which are actually unsuitable for direct compression. In addition, the mechanical stability of the produced tablets was distinctly improved by application of lower punch vibration, whereby the occurrence of segregation was comparatively low. CONCLUSION: In summary, lower punch vibration allows a more efficient die filling, whereby the powder flow as well as mechanical stability of the tablets are improved.

Performance Characteristics of a Novel Vibration Technique for the Densification of a Powder Bed within a Die of a Rotary Tablet Press - a Proof of Concept.

The aim of this study was to investigate the concept of lower punch vibration as a possible approach to densify the powder bed within the die of a rotary tablet press. Therefore, a laboratory vibration equipment was developed to obtain a better understanding of the performance characteristics and effects of a pneumatically generated vibration system on pharmaceutical powders. For this purpose, two widely used pharmaceutical powders, basic magnesium carbonate (Pharmagnesia MC Type F) and microcrystalline cellulose (Ceolus® KG1000), both with different physical properties, were investigated. The powders were characterized by laser diffraction, scanning electron microscopy, helium pycnometry, ring shear testing, gas adsorption, and by determination of the powder flowability. Furthermore, the extent of densification within the die during vibration was visualized by a high-speed camera system and analyzed by an image-analyzing software. It was observed that lower punch vibration was able to densify the powder bed to a sufficient extent and within an adequate time period. Consequently, the presented results revealed that lower punch vibration may be a promising technique to remove entrapped air from powder beds, thus obtaining a denser powder bed within the die, which might potentially improve the tableting process and prevent complications during tablet manufacture.